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The Journal of Neuroscience, March 1, 2000, 20(5):1666-1674
Declines in mRNA Expression of Different Subunits May Account for
Differential Effects of Aging on Agonist and Antagonist Binding to the
NMDA Receptor
Kathy R.
Magnusson
Department of Anatomy and Neurobiology, College of Veterinary
Medicine and Biomedical Sciences, Colorado State University, Fort
Collins, Colorado 80523-1670
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ABSTRACT |
The purpose of the present study was to determine whether some of
the age-related changes that occur in binding to the NMDA receptor
complex can be accounted for by changes in subunit expression during
the aging process. In situ hybridization for the NMDA
subunits  1,  1, and 2, and receptor autoradiography, using the
agonist glutamate and the competitive antagonist
[(±)-2-carboxypiperazin-4-yl] propyl-1-phosphonic acid (CPP), were
performed on sections from C57Bl/6 mice representing three different
age groups (3, 10, and 30 months of age). There was a significant
overall decrease between 3 and 30 month olds in the density of mRNA for
the 1 subunit in the cortex and hippocampus, but only a few
individual brain regions exhibited significant declines. The mRNA for
the 2 subunit was significantly decreased in a majority of cortical
regions and in the dentate granule cells. Emulsion analysis indicated that the change in the density of 2 subunit mRNA in the inner frontal cortex was primarily attributable to a decrease in the amount
of messages per cell. Age-related changes in mRNA density of the 2
subunit correlated with changes in NMDA-displaceable [3H]glutamate binding, and mRNA density changes in
the 1 subunit showed a significant relationship with changes in
[3H]CPP binding in the 30-month-old mice.
These results suggest that changes during aging in the expression of
different subunits of the NMDA receptor may account for the
differential effects of aging on agonist versus antagonist binding to
the NMDA binding site.
Key words:
NMDA receptors; NMDA subunits; in situ
hybridization; glutamate; aging; mRNA
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INTRODUCTION |
Memory declines are the earliest
cognitive dysfunctions to be detected during the aging process (Albert
and Funkenstein, 1992 ). Age-related deficits in memory performance are
seen in humans and nonhuman primates (Gallagher and Nicolle, 1993;
Gallagher and Rapp, 1997), dogs (Head et al., 1995), and rodents (Gage
et al., 1984; Rapp et al., 1987; Barnes, 1988; Pelleymounter et al., 1990). The NMDA receptor, a subtype of glutamate receptor, is important in learning and memory functions (Cotman et al., 1989; Magnusson, 1998b). Antagonists of the NMDA receptor block the initiation of long-term potentiation in the hippocampus (Harris et al.,
1984; Morris et al., 1986; Bashir et al., 1991) and neocortex (Artola
and Singer, 1994) and interfere with performance of learning and memory
tasks (Alessandri et al., 1989; Mondadori et al., 1989; Heale and
Harley, 1990; Morris and Davis, 1994).
Aging animals exhibit declines in NMDA receptor binding densities and
functions. NMDA-stimulated release of transmitters is decreased with
increasing age (Gonzales et al., 1991; Pittaluga et al., 1993).
Long-term potentiation is also negatively altered in aged rodents
(Barnes and McNaughton, 1985; Deupree et al., 1993). Age-related
declines in binding of glutamate and [(±)-2-carboxypiperazin-4-yl] propyl-1-phosphonic acid (CPP) to NMDA binding sites are seen in mice,
rats, and monkeys (Kito et al., 1990; Pelleymounter et al., 1990;
Tamaru et al., 1991; Wenk et al., 1991; Magnusson, 1995). Humans also
exhibit declines with increased age in binding of
[3H]MK801 to the NMDA receptor in the
frontal cortex (Piggott et al., 1992). Changes in NMDA binding sites
during aging in both frontal cortical regions (Magnusson, 1998a) and in
the hippocampus (Pelleymounter et al., 1990; Magnusson, 1998a) have
been correlated with poor performance in reference memory tasks.
The effects of aging on the different binding sites of the NMDA
receptor complex are not homogeneous (Magnusson, 1995). In addition,
differences occur between antagonist and agonist binding to the NMDA
binding site; [3H]CPP binding densities
decline similarly during aging to NMDA-displaceable [3H]glutamate binding in the cerebral
cortex of mice (Magnusson, 1995), but differ in the degree of change in
the hippocampus (Pelleymounter et al., 1990; Magnusson, 1995; Nicolle
et al., 1996). The mechanisms that are responsible for these
heterogeneous effects are not known.
Functional subunits of the NMDA receptor complex have been cloned for
mice (Ikeda et al., 1992; Kutsuwada et al., 1992; Meguro et al., 1992;
Yamazaki et al., 1992). The 1 (rat NR1) subunit has the same
distribution as NMDA-displaceable
[3H]glutamate binding (Moriyoshi et al.,
1991; Meguro et al., 1992; Nakanishi, 1992). There are four members of
the family of subunits, 1-4 (rat NR2A-D), in the mouse (Ikeda
et al., 1992; Kutsuwada et al., 1992; Meguro et al., 1992). These
subtypes confer different agonist-antagonist affinities to 1/
heteromeric receptors (Kutsuwada et al., 1992; Yamazaki et al.,
1992).
The purpose of the present study was to determine whether some of the
age-related changes that occur in binding to the NMDA receptor complex
can be accounted for by changes in subunit expression during the aging process.
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MATERIALS AND METHODS |
Animals
Thirty-six male C57Bl/6 mice (National Institute on Aging,
Bethesda, MD) representing three different age groups (3, 10, and 30 months of age) were fed ad libitum and housed under 12 hr
light/dark conditions for 3-7 d before killing. The mice were
killed by exposure to CO2, followed by
decapitation. The brains were removed, frozen on dry ice, and stored in
a  70°C freezer. Twenty micrometer horizontal sections were cut from
the brain with a Zeiss Microm 500 cryostat and placed on gel-coated
slides, which were stored at 70°C until used. Sections from two
different members of each age group were present on each slide, and the
order of placement on the slide was varied between cutting groups.
In situ hybridization
Oligonucleotides (45 bases) were commercially prepared
(Macromolecular Resources, Colorado State University) for the 1
(complimentary to nucleotide residues 54 to 10), 1 (2901-2945),
and 2 (3107-3151) subunits of the mouse NMDA receptor (Watanabe et
al., 1992, 1993) and were labeled with
33P-dATP using terminal
deoxyribonucleotidyl transferase (New England Nuclear, Boston, MA) and
NENSORB20 purification cartridges (New England Nuclear). In
situ hybridization was performed according to the method of
Watanabe et al. (1992, 1993). Each solution step was performed with
gentle rotation on a rotating table except for the fixation and
hybridization steps. Slides with sections were thawed, air-dried, fixed
in 4% paraformaldehyde-PBS, pH 7.2 (25°C) for 15 min, placed
in 2 mg/ml glycine in PBS, pH 7.2 (25°C) for 20 min, and placed in
0.25% acetic anhydride-0.1 M triethanolamine, pH 8.0 (25°C) for 10 min. Slides were placed in coplin jars for 2 hr
in a prehybridization solution that consisted of 50% formamide, 0.1 M Tris-HCl, pH 7.5, 4× SSC (1× SSC = 150 mM NaCl and 15 mM sodium
citrate), 0.02% Ficoll, 0.02% polyvinylpyrrolidone, 0.02% bovine
serum albumin, 2% sarkosyl, and 250 µg/ml salmon testes DNA.
Chemicals were purchased from Sigma (St. Louis, MO). Slides were then
successively washed for 5 min each in 2× SSC, 70 and 100% ethanol,
and air-dried for 15 min. Hybridization was performed by placing 100 µl of prehybridization solution with 10% dextran sulfate and 1 × 106 dpm of
33P-labeled oligonucleotide probe added
onto the slides, coverslipping the slides with parafilm, and incubating
them for 18 hr in a 42°C oven humidified with 5× SSC. Coverslips
were removed, and slides were rinsed for 40 min each in 2× SSC and
0.1% sarkosyl (25°C) and twice in 0.1× SSC and 0.1% sarkosyl
(55°C) and air-dried. Nonspecific binding was determined by addition
of 20-fold excess cold oligo to the hybridization solution on some
slides. Sections were exposed to Hyperfilm- max (Amersham,
Piscataway, NJ) for 3-5 d along with brain paste standards. The
standards were prepared by homogenizing whole brain from 12 3-month-old
mice and mixing in measured amounts of
33P-dATP (Marks et al., 1992). The actual
concentrations were determined by scintillation counting of weighed
aliquots and ranged from 95,000 to 14 cpm/mg wet weight of brain
tissue. Brain and standard images were captured using a Macintosh IIci
computer with a Quickcapture board, a Panasonic CCD camera, and NIH
Image software. Quantitative densitometry was performed on the images
from four sections for total binding and two sections for nonspecific
binding from each animal with the use of NIH Image software. The
standards were used to convert optical density to counts per minute per
milligram of tissue. Specific signal was determined by
subtracting nonspecific binding from total binding. Slides were then
dipped in photographic emulsion (NTB2; Eastman Kodak, Rochester, NY),
exposed for 8-12 weeks, developed in D19 developer (Eastman Kodak),
and counterstained with a Giemsa stain. Images of cells and grains
within specific brain regions were captured on the computer as
described above. Grain area was determined by filtering images to
highlight grains (Smolen and Beaston-Wimmer, 1990), thresholding, and
analyzing particles within 12 cells per slide for a total of 48 cells
for total binding and 24 cells for nonspecific binding for each animal (Watanabe et al., 1993). An overall average for cells and for animals
was calculated, and specific binding was determined as described for
film analysis.
Autoradiography
NMDA binding sites. Binding was performed as
previously described (Magnusson, 1995). Slides were preincubated in
cold (4°C) 50 mM Tris acetate (TA) buffer, pH 7.0, for 30 min, followed by 2× 10 min incubations in warm TA buffer, pH 7.0 (30°C). Sections were then incubated in a solution of 100 nM
[3H]L-glutamate (New England
Nuclear), 1 µM kainate, 5 µM AMPA, and 100 µM
4-acetamido-4'-isothiocyanotostilbene-2,2'-disulfonic acid
for 10 min at 4°C. Slides were rinsed in four changes of TA buffer
(4°C) for a total of 30 sec and dried by a stream of compressed air
at room temperature. Unlabeled 200 µM NMDA was added to
the incubation solution for determining nonspecific binding.
CPP binding sites. Binding was performed as previously
described (Magnusson, 1995). Slides were preincubated in 50 mM TA buffer, pH 7.6, for 30 min at 4°C, followed by 2×
10 min incubations in TA buffer at 30°C. Tissue was incubated in a
solution containing 100 nM
[3H]CPP (New England Nuclear) for 20 min
at 4°C for total binding. Nonspecific binding was determined by the
addition of 100 µM unlabeled CPP to the incubation
solution. Slides were rinsed in four changes of TA buffer for 15 sec at
4°C and dried by a stream of compressed air at room temperature.
Slides were allowed to dry overnight and were apposed to
tritium-sensitive film (Amersham) along with tritium standards
(Amersham) at 20°C for 10 d. Exposed films were developed in
D-19 developer (Eastman Kodak). Brain images were captured and analyzed
as described for in situ hybridization. Tritium standards
were used to convert optical density measurements to femtomoles per
milligram of protein for each brain region analyzed. Specific binding
was determined by subtracting nonspecific binding from total binding.
Statistical analysis. Age-related differences in densities
of mRNA and receptor binding were analyzed by ANOVA followed by Fisher's modified LSD using either SPSS or GB-Stat software.
Examination of age-related differences within brain regions was part of
the original plan. Correlational analysis was done by examining the relationships between age-related changes in receptor binding and mRNA
densities across multiple brain regions. Separate analyses were
performed for 10- and 30-month-old mice. The receptor binding or mRNA
density within each brain region in 10- and 30-month-old mice was
expressed as a percentage of the average binding or mRNA density for 3 month olds within that brain region. The percentages for each animal
within an age group were averaged to obtain a mean percentage of
3-month-old binding or mRNA density for that age group within each
brain region. These means for receptor binding for individual brain
regions were plotted against the respective percentage of 3-month-old
mRNA densities within the same regions, and Pearson's correlation
coefficients were obtained.
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RESULTS |
1 subunit mRNA
There was a significant main effect of age,
F(2,34) = 4.29, p = 0.022, and brain region, F(14,476) = 637, p < 0.001, on density (counts per minute per
milligram of tissue) of mRNA for the 1 subunit of the NMDA
receptor (Fig. 2A,B). There was also a significant interaction between age and brain region,
F(28,476) =1.72, p = 0.013. Densities of mRNA for the 1 subunit were higher in the major
cell layers of the hippocampus than in the subregions of the cortex in
all ages of mice (Figs.
1A-D,
2A,B). Within individual brain regions, the 30 month
olds showed significant decreases from densities seen in 3-month-old
mice in layers II-III of the frontal and occipital/temporal cortices,
in the granule cells of the ventral blade of the dentate gyrus, and in
the caudate nucleus (Fig.
2A,B). There was also a
significant decrease in the density of the mRNA for the 1 subunit
between 3 and 10 months of age in the ventral blade of the dentate
gyrus granule cell layer (Fig. 2A,B).
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Figure 1.
In situ hybridization for NMDA
subunits in different ages of mice. Film autoradiograms of the
hybridized mRNA for 1 (A-C), 1
(E-G), and 2 (I-K)
subunit of the NMDA receptor in 3 (A, E, I)-, 10 (B, F, J)-, and 30 (C, G,
K)-month-old mice. D, H, L, Densities
(counts per minute per milligram of tissue) of binding for
different gray levels for the 1 probe in A-C
(D), 1 probe in E-G
(H), and 2 probe in I-K
(L).
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Figure 2.
Quantitative comparison of mRNA densities for NMDA
subunits within brain regions of different ages of mice. Densities
(counts per minute per milligram of tissue) of mRNA for the 1
(A, B), 1 (C, D), and 2 (E,
F) subunits of the NMDA receptor in different cortical
(A, C, E) and hippocampal and subcortical (B, D,
F) regions in 3-, 10-, and 30-month-old mice. *
indicates p < 0.05 for difference from 3-month-old
mice. # indicates p < 0.05 for difference from
10-month-old mice. A-D, n = 12 for
3 and 10 month olds, n = 13 for 30 month olds.
E, F, n = 11 for 3 month olds,
12 for 10 month olds, and 10 for 30 month olds. in,
Cortical layers IV-VI; out, cortical layers II-III;
Fron, frontal; Par, parietal;
O/T, occipital/temporal; Ento,
entorhinal; pyr, pyramidal cell layer;
DGL, dentate granule cell layer; dors,
dorsal blade; vent, ventral blade;
Cerebell, cerebellum.
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1 subunit mRNA
There was a significant main effect of brain region,
F(14,476) = 779, p < 0.001, on densities of mRNA for the 1 subunit of the NMDA receptor.
There was no significant main effect of age, F(2,34) = 0.83, p = 0.44, and no significant interaction between age and brain region,
F(28,476) = 1.15, p = 0.27 (Fig. 2C,D). Average densities were higher in the major
cell layers of the hippocampus than in the layers of the cortex in all
ages (Figs. 1E-H, 2C,D). No brain regions
showed significant changes during aging in the density of mRNA for the
1 subunit (Fig. 2C,D).
2 subunit mRNA
There was a significant main effect of age,
F(2,30) = 7.89, p = 0.002, and brain region, F(13,390) = 1275, p < 0.001, on densities of mRNA for the 2
subunit of the NMDA receptor. There was no significant interaction
between age and brain region,
F(26,390) = 1.4, p = 0.095. Densities for 2 mRNA were highest in the major cell layers of
the hippocampus than in the cortex, and there was a higher density in
layers II-III of the cortex than in the inner layers in all ages
examined (Figs. 1I-L,
2E,F). Within brain regions, the 2 mRNA was
significantly decreased between 3 and 30 months of age in all cortical
regions, except the cingulate cortex, in the granule cell layer of the
dentate gyrus, and in the caudate nucleus (Fig.
2E,F). Layers II-III of the frontal cortex
also showed significant reductions in mRNA density between 10- and 30-month-old mice (Figs. 1J,K,
2E).
Emulsion analysis of mRNA for subunits of the NMDA receptor
The average specific grain area per cell in different ages of mice
was examined to determine whether the declines in mRNA density for the
1 and 2 subunits of the NMDA receptor were attributable to a
decrease in message per cell or a decrease in cell numbers with message
density maintained within the remaining cells. We used average grain
area per cell, as opposed to numbers of grains, to take into account
that one or more messages in close proximity could have produced silver
grains that coalesced into a single grain (Smolen and Beaston-Wimmer,
1990). A representative field, exhibiting cells from the inner layers
(IV-VI) of the frontal cortex overlain with silver grains (black
dots), is shown in Figure 3A.
The analysis of the outer cortex included both layers II and III, but
analysis of the inner layers was concentrated on the layer V pyramidal
cells. There was a significant decrease in grain area per cell for 2
mRNA between 3 and 30 months of age in the inner layers of the frontal
cortex (Fig. 3B). Both 2 and 1 mRNA exhibited
significant declines in grain area per cell in the frontal cortex
between 10 and 30 months of age (Fig. 3B). A frequency distribution of the data for the average grain area per cell for 2
mRNA in the inner frontal cortex was graphed. The bin size was based on
the average size of one grain. The results showed a shift in aged mice
to a larger percentage of cells with fewer or no grains per cell when
compared with 3-month-old mice (Fig. 3C).
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Figure 3.
Age-related changes in the amount of mRNA for the
NMDA subunits within neurons of the frontal cortex. A,
Computer image of an emulsion-dipped slide showing cells in layer V of
the frontal cortical region in a 3-month-old mouse. This image was
captured by focusing on the silver grains and was then filtered as
described in Materials and Methods to enhance the contrast. Black
silver grains were primarily located over Giemsa-stained cells.
B, Graph of the average specific grain area per cell for
the mRNA for the 2 or 1 subunits in the outer (II-III) and/or
the inner (IV-VI) layers of the frontal cortex in 3-, 10, and
30-month-old mice. C, Frequency graph of the percentage
of total cells within each age group that contained the average
specific grain area within each bin for the 2 subunit mRNA in the
inner frontal cortex. The bin size was chosen as the average grain
size. * indicates p < 0.05 for difference from
3-month-old mice. # indicates p < 0.05 for
difference from 10-month-old mice. Legend numbers indicate age in
months.
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NMDA-displaceable [3H]glutamate binding
There was a significant effect of age,
F(2,31) = 9.165, p = 0.0007 and brain region, F(18,558) = 235, p < 0.0001, on NMDA-displaceable [3H]glutamate binding in C57Bl/6 mice,
but no significant interaction between age and brain region,
F(36,558) = 0.3109, p = 1. Age-related declines in binding of glutamate to NMDA binding sites
were grossly detectable in some brain regions in autoradiographic
images (Fig. 4A-D).
Significant decreases in [3H]glutamate
binding between 3 and 30 months of age were found throughout the
cerebral cortex, in the caudate nucleus, and in all but one hippocampal
region analyzed (Fig. 5A,B).
Significant declines in binding were also seen between 3 and 10 months
of age in several hippocampal regions (Fig. 5B).
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Figure 4.
NMDA-displaceable
[3H]glutamate and [3H]CPP
binding to the NMDA receptor in different ages of mice. Film
autoradiograms for the NMDA-displaceable
[3H]glutamate (A-C) and
[3H]CPP (E-G) binding in 3 (A, E)-, 10 (B, F)-, and 30 (C, G)-month-old mice. D, H, Densities
(femtomoles per milligram of protein) of binding for different gray
levels for [3H]glutamate binding in
A-C (D) and
[3H]CPP binding in E-G
(H).
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Figure 5.
Quantitative comparison of NMDA-displaceable
[3H]glutamate and [3H]CPP
binding within brain regions of different ages of mice. Densities
(femtomoles per milligram of protein) of binding for NMDA-displaceable
[3H]glutamate (A, B) and
[3H]CPP (C, D) binding in different
cortical (A, C) and hippocampal and subcortical
(B, D) regions in 3-, 10-, and 30-month-old mice. *
indicates p < 0.05 for difference from 3-month-old
mice. # indicates p < 0.05 for difference from
10-month-old mice. A, B, n = 12 for
3 month olds and 11 for 10 and 30 month olds. C, D,
n = 6 for all ages. Cg, Cingulate
cortex; Fr, frontal cortex; in, cortical
layers V-VI for parietal cortex and IV-VI for all others;
out, cortical layers I-III; Par,
parietal cortex; mid, cortical layer IV;
O/T, occipital/temporal; Ent, entorhinal;
l/m, stratum lacunosum/moleculare; rad,
stratum radiatum; or, stratum oriens; DG,
dentate granule molecular layer; dor, dorsal blade;
ven, ventral blade; Cau, caudate;
Cb, cerebellum.
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[3H]CPP binding
There was a significant effect of age,
F(2,15) = 5.1907, p = 0.02, and brain region, F(18,270) = 287, p < 0.0001, on
[3H]CPP binding to NMDA receptors. There
was also a significant interaction between age and brain region,
F(36,270) = 2.36, p < 0.0001. Decreased density of binding with increased age was grossly
detectable in some brain regions in autoradiographic images (Fig.
4E-H). Significant decreases in
[3H]CPP binding were found between 3 and
30 months of age in all but one cortical region and in all hippocampal
regions analyzed (Fig. 5C,D). The 30-month-old mice had
significantly less binding than 10 month olds in 6 of 10 cortical
regions, the dentate gyrus molecular layer, and in stratum oriens of
the CA3 region (Fig. 5C,D). Ten-month-old mice had a
lower density of binding than 3 month olds in the occipital/temporal
cortex and in all hippocampal regions analyzed (Fig.
5C,D).
Correlations between NMDA subunit mRNA and binding to the
NMDA receptor
Correlations were performed using age-related changes in binding
and mRNA densities across multiple brain regions and were done
separately for 10- and 30-month-old mice. Significant correlations were
found between age-related changes in NMDA-displaceable
[3H]glutamate binding and mRNA densities
for the 2 subunit of the NMDA receptor in the 30-month-old mice
(Fig. 6A, Table
1). Changes in 1 mRNA density between
3 and 30 months of age correlated significantly with changes in
[3H]CPP binding (Fig.
6B, Table 1). No other correlations were significant,
including the correlation between age-related changes in
NMDA-displaceable [3H]glutamate and
[3H]CPP binding (Fig. 6C,
Table 1).
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Figure 6.
Correlations between age-related changes in mRNA
density for NMDA subunits and ligand binding across cortical,
hippocampal, and striatal brain regions in 30-month-old mice.
A-C, Graphs of the relationships between the percentage
of densities in 3 month olds remaining in 30 month olds for 2 mRNA
and NMDA-displaceable (NMDA-disp.)
[3H]glutamate binding (A),
1 mRNA and [3H]CPP binding
(B), and NMDA-displaceable
[3H]glutamate and [3H]CPP
binding (C), obtained by plotting the mean values
for different brain regions. Pearson correlation coefficients for each
graph are presented in Table 1. 1, Cingulate cortex;
2, frontal inner (IV-VI) cortex; 3,
frontal outer (II-III) cortex; 4, parietal inner
(V-VI) cortex; 5, parietal outer (II-III) cortex;
6, caudate nucleus; 7, occipital/temporal
inner (IV-VI) cortex; 8, occipital/temporal outer
(II-III) cortex; 9, entorhinal inner (IV-VI) cortex;
10, entorhinal outer (II-III) cortex;
11, ventral blade of dentate molecular layer
(binding)/ventral dentate granule cell layer (in situ);
12, dorsal blade of dentate molecular layer
(binding)/dorsal dentate granule cell layer (in situ);
13, CA1 stratum lacunosum/moleculare (binding)/CA1
pyramidal cell layer (in situ); 14, CA1
stratum radiatum (binding)/CA1 pyramidal cell layer (in
situ); 15, CA1 stratum oriens (binding)/CA1
pyramidal cell layer (in situ); 16, CA3
stratum radiatum (binding)/CA3 pyramidal cell layer (in
situ); 17, CA3 stratum oriens (binding)/CA3
pyramidal cell layer (in situ). All outer regions
included layers I-III for receptor binding.
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Table 1.
Pearson correlation coefficients for age-related changes in
mRNA densities for NMDA subunits and densities of ligand binding to
NMDA receptors
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DISCUSSION |
The primary finding of this study was that there was an
age-related decline in the density of mRNA for the 2 subunit of the NMDA receptor throughout most of the cerebral cortex and in the dentate
granule cells in C57Bl/6 mice. Examination at the cellular level in the
inner layers of the frontal regions of the cortex showed a decline in
the amount of mRNA for 2 within the cell in 30-month-old mice as
compared to 3 month olds. This change during the aging process between
3 and 30 months of age in mRNA expression for the 2 subunit appeared
to be related to the changes seen in agonist, NMDA-displaceable
[3H]glutamate, binding within the cortex
and hippocampus. The 1 subunit also exhibited an overall decline
with age that showed a relationship with changes in antagonist,
[3H]CPP, binding in 30-month-old mice.
The distributions of the 1, 1, and 2 messages in this study
were similar to those reported by Watanabe et al. (1993). During aging,
there was an overall significant decrease in the mRNA for the 1
subunit of the NMDA receptor throughout the regions analyzed, however,
within brain regions only a few changes were significant. The
age-related declines in the message for the 2 subunit within brain
regions, on the other hand, were significant throughout the cortex and
in the granule cells of the dentate gyrus. The 1 mRNA did not show
significant changes during aging. The data for the 1 subunit
appeared to suffer from a greater variability between animals than was
seen with the other two subunits.
Our preliminary experiments with immunoblots showed declines in the
expression of the proteins for both 1 and 2 subunits in
homogenates of whole cortex between 3 and 30 months of age (Kuehl-Kovarik et al., 1998). The protein expression of the 1 subunit suffered from variability similar to the mRNA analysis (Kuehl-Kovarik et al., 1998). These results suggest that the
age-related changes in mRNA expression for specific subunits of the
NMDA receptor in the mouse are accompanied by changes in protein
expression. Aged monkeys also show a decline in the expression of the
NR1 subunit at the protein level in the distal dendrites of the dentate gyrus (Gazzaley et al., 1996), which is consistent with our mRNA results. Changes during aging in the protein expression of all three
subunits have been reported in the hippocampus and striatum of
Long-Evans rats (Wang et al., 1996). The NR1 protein is decreased in
the hippocampus, and declines in the protein expression of NR1, NR2A,
and NR2B are seen in the frontal cortex of patients with Alzheimer's
disease (Wang et al., 1997), a disease that is associated with aging
and memory deficits (Terry and Katzman, 1983).
The decrease in density of mRNA for the 2 subunit discovered in the
film analysis could have been attributable to a decreased amount of
message per cell, a loss of cells with maintenance of message in the
remaining cells, or a combination of both. The analysis of silver
grains in the inner frontal cortex indicated that at least a portion of
the change in message with increasing age was attributable to a
decrease in the amount of message per cell. Although this does not rule
out a contribution of cell loss, the percentage of decline in amount of
message per cell was greater than the change seen in density on film,
which argues against cell loss being a major cause of the change. In
addition, the new stereological techniques of cell counting indicate
that cell loss in the brain during aging is not as prevalent as once
was believed (West et al., 1994; Rapp and Gallagher, 1996).
The increased message per cell in the 10-month-old mice as compared to
the old mice was not predicted by the film analysis. The emulsion
analysis showed significantly less cells with no message and suggested
that there was an increased number of cells with higher amounts of
grain area per cell in the 10 month olds, as compared to the old mice.
More message within a minority of cells might not have influenced the
average density of the brain region in film analysis because of the
relative lack of silver grains over the neuropil that also contributed
to the average. These results suggest that the changes in the NMDA
receptors that occur during aging are not one continuous process from
young adulthood to old age.
The age-related changes in NMDA-displaceable
[3H]glutamate and
[3H]CPP binding to the NMDA receptor
were similar to our previous findings, with a few exceptions
(Magnusson, 1995). The significant changes between 10 and 30 month olds
in this study were seen in less regions for
[3H]glutamate binding and in more
regions for [3H]CPP (Magnusson, 1995).
Some variables between the studies include different colonies of mice
and different thicknesses of sections (Magnusson, 1995). However, the
major finding of greater differences in percentage of decline between
[3H]CPP and
[3H]glutamate binding occurring in the
hippocampus as compared to the cortex was consistent between the two
studies. This difference in the hippocampus has also been seen in
Long-Evans rats (Pelleymounter et al., 1990; Nicolle et al.,
1996).
Based on the correlations, it appeared that the changes that occurred
in the aged mice in agonist
([3H]glutamate) binding in many of the
cortical and hippocampal regions were related to changes in the mRNA
expression of the 2 subunit of the NMDA receptor. Heteromeric
receptors that contain 1 and 2 subunits exhibit a higher affinity
for agonist binding (i.e., twofold and 4.3- to 10-fold higher
affinities for glutamate and glycine, respectively) than those in which
1 is paired with the 1 subunit (Kutsuwada et al., 1992; Priestley
et al., 1995). Our agonist binding results may be explained by a shift
in the population of receptors during aging toward more receptors with
a low affinity for agonist. Even though the densities of the mRNA for
the 1 subunit did not change to the same degree as
[3H]CPP binding, the alterations
appeared to be related across brain regions. Because the 1 subunit
is believed to be necessary to produce functional receptors (Moriyoshi
et al., 1991; Kutsuwada et al., 1992; Meguro et al., 1992; Ishii et
al., 1993), it does not seem likely that the greater decline in CPP
than glutamate binding could be due to an overall loss of the 1
subunit. The splice variants of the 1 subunit, however, can confer
different agonist/antagonist affinities to the receptors (Hollmann et
al., 1993). It is possible that changes in one or more of the 1
splice variants may contribute to the differential effect of aging on agonist versus antagonist binding in the hippocampus.
The age-related changes in binding of
[3H]glutamate to NMDA receptors in the
frontal cortical regions and [3H]CPP
binding in the hippocampus have been associated with decreased performance in the Morris water maze, a spatial memory task
(Pelleymounter et al., 1990; Magnusson, 1998a). The results of the
correlational analyses suggest that changes in the 2 and 1
subunit may be related to the memory changes as well. Prediction of the
consequences of the changes in the 1 subunit will have to await
further investigations into the splice variants and protein expression.
The age-related changes in the 2 subunit could have many potential
consequences. The atypical, noncompetitive antagonist ifenprodil has a
300-429 fold higher potency for the 1/2 receptors than the
1/1 combination (Williams, 1993; Priestley et al., 1995;
Gallagher et al., 1996). The 1/2 receptors are also more
sensitive to polyamines (Lynch et al., 1995) and butyrophenones, such
as haloperidol, droperidol, and spiperone (Lynch and Gallagher, 1996;
Yamakura et al., 1998), than receptors composed of 1 and 1
subunits. With respect to electrophysiological properties, the
1/2 receptor has a slower offset time (380 msec) than the
1/1 receptors (120 msec) (Monyer et al., 1992; Seeburg et al.,
1994). This means that the sensitivities to drugs and endogenous
ligands and the channel open time could all be altered by declines in
the expression of the 2 subunit during aging.
The 2 subunit, but not the 1 or 1 subunit, contains the
binding site necessary for autophosphorylation-dependent targeting of
calcium/calmodulin-dependent kinase II (CaMKII), which in turn is
essential for NMDA-dependent LTP (Strack and Colbran, 1998). There also
is a relationship between the induction of the expression of the 2
subunit and the persistence of LTP (Williams et al., 1998). The
age-related changes in the 2 subunit may, at least in part, account
for the declines in the expression and persistence of LTP that have
been reported in aged animals (Barnes, 1979; Barnes and McNaughton,
1985; Baskys et al., 1990). Additional evidence for the importance of
this subunit in learning and memory processes has been provided by
transgenic mice in which the 2 (NR2B) subunit was overexpressed
(Tang et al., 1999). These mice show enhanced long-term potentiation
and learning abilities.
In conclusion, the differential effects of aging on agonist versus
antagonist binding in the hippocampal region appear to be related to
changes in two different subunits of the NMDA receptor. A determination
of why certain subunits are more influenced by the aging process than
others will be necessary before it can be determined whether effective
interventions can be designed to prevent this change in the NMDA
receptor and potentially reduce the memory declines associated with aging.
| |
FOOTNOTES |
Received Aug. 23, 1999; revised Dec. 7, 1999; accepted Dec. 10, 1999.
This research was supported by a First Independent Research Support and
Transition Award AG10607 (K.R.M.) and Research Career Development Award
AG00659 (K.R.M.). I acknowledge Dr. Scott Nelson for technical advice
on the project and Ginger Sammonds, Sarah Zimmerman, and Tara Hogan for
their technical assistance.
Correspondence should be addressed to Dr. Kathy Magnusson, Department
of Anatomy and Neurobiology, College of Veterinary Medicine and
Biomedical Sciences, Colorado State University, Fort Collins, CO
80523-1670. E-mail: kmagnuss{at}lamar.colostate.edu.
| |
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ABSTRACT
INTRODUCTION
