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The Journal of Neuroscience, September 1, 2001, 21(17):6949-6956
Acetylcholine Mediates the Estrogen-Induced Increase in NMDA
Receptor Binding in CA1 of the Hippocampus and the Associated
Improvement in Working Memory
Jill M.
Daniel and
Gary P.
Dohanich
Department of Psychology, Tulane University, New Orleans, Louisiana
70118
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ABSTRACT |
Elevated levels of circulating estrogen in female rats result in
increased spine and synapse density and parallel increases in NMDA
receptor binding in area CA1 of the hippocampus. Estrogen also
influences cholinergic neurochemistry in the basal forebrain and
hippocampus. The objectives of the present study were to determine the
role of acetylcholine in the estrogen-induced increase in NMDA receptor
binding in CA1 of the hippocampus and to investigate the relationship
between increased NMDA receptor binding in CA1 and performance on a
task of working memory. In the current experiments, elevating
endogenous levels of acetylcholine in ovariectomized rats by
3 d of continuous administration of physostigmine, an acetylcholinesterase inhibitor, increased NMDA receptor binding in CA1
as measured by quantitative autoradiography. This increase was
comparable with the increase in NMDA receptor binding induced by
injections of estradiol benzoate 72 and 48 hr before death. Additionally, the administration of
5,11-dihydro-8-chloro-11-[[4-[3-[(2,2-dimethyl-1-oxopentyl)ethylamino]propyl]-1-piperidinyl]acetyl]-6H-pyrido[2,3-b][1,4]benzodiazepin-6-one (BIBN 99), an M2 receptor antagonist, blocked the ability of
both estrogen and physostigmine to increase NMDA receptor binding. The
regimen of estradiol replacement that was demonstrated to increase NMDA
receptor binding in CA1 of ovariectomized rats also improved arm-choice
accuracy in a working memory task in an eight-arm radial maze. The
estrogen-induced improvement in working memory performance was blocked
by BIBN 99, which also blocked the increase in NMDA receptor binding.
These results indicate that acetylcholine acts at M2 muscarinic
receptors to mediate the estrogen-induced increase in NMDA receptor
binding in CA1 of the hippocampus as well as the associated improvement
in working memory.
Key words:
estrogen; acetylcholine; hippocampus; learning; memory; NMDA receptors; M2 muscarinic receptors
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INTRODUCTION |
The ovarian hormone estrogen affects
performance on various measures of learning and memory in mammals,
although the mechanisms underlying these effects are unknown. Estrogen
induces morphological changes and modulates excitatory and inhibitory
neurotransmission in the hippocampus, an area of the brain implicated
in learning and memory. For example, spine and synapse density on CA1
pyramidal cells is positively correlated with estrogen levels, as
indicated by experiments in which exogenous estrogen was manipulated
(Gould et al., 1990 ) and in which estrogen levels varied across the rat estrous cycle (Woolley et al., 1990). Interestingly, estradiol-induced increases in spine density in CA1 correlated positively to increased NMDA but not AMPA receptor binding as well as to increased
sensitivity of CA1 pyramidal cells to NMDA but not AMPA
receptor-mediated synaptic input (Woolley et al., 1997). In addition to
increasing the density of dendritic spines on pyramidal cells in
vitro (Murphy and Segal, 1996), estradiol decreased levels of
glutamic acid decarboxylase (GAD), the GABA-synthesizing enzyme, and
decreased GABAergic miniature IPSCs (Murphy et al., 1998),
indicating that estradiol-induced spine formation results from a
disinhibition of hippocampal pyramidal cells that occurs after
reduction of GABAergic inhibition.
Transection of the fimbria/fornix, which contains the majority of the
subcortical afferents to the hippocampus, prevented an
estradiol-induced increase in dendritic spine density on CA1 pyramidal
cells (Leranth et al., 2000). The fimbria/fornix contains the
cholinergic input to the hippocampus from the medial septal/diagonal band complex (Paxinos, 1995). Estrogen facilitates cholinergic neurotransmission in the septal-hippocampal pathway as evidenced by
its ability to increase activity and mRNA of choline acetyltransferase (Luine, 1985; Gibbs and Pfaff, 1992; Gibbs et al., 1994), high-affinity choline uptake (O'Malley et al., 1987; Singh et al., 1994), and acetylcholine release (Gibbs et al., 1997). Acetylcholine regulates hippocampal GABA release via action at the M2 subtype of the muscarinic receptor located on axon terminals of GABAergic basket and chandelier cells, interneurons that provide powerful input to pyramidal cells (Freund and Gulyas, 1997; Hajos et al., 1998). Thus, these
presynaptically located M2 receptors provide a mechanism by which the
estrogen-induced elevation of acetylcholine could reduce hippocampal
GABA release resulting in disinhibition of CA1 pyramidal cells.
Although estrogen affects learning and memory performance, to date
there are no published reports that associate the estradiol-induced changes in spine density and NMDA receptor binding in CA1 to
improvements in performance on tasks that measure learning and memory.
Estrogen impairs or has no effect on tasks dependent on spatial
reference memory, defined as memory for information consistent across
trials (Galea et al., 1995; Berry et al., 1997; Warren and Juraska,
1997; Daniel et al., 1999; Miller et al., 1999; Wilson et al., 1999; Chesler and Juraska, 2000). However, constant levels of estrogen present over a number of days or weeks enhance performance on tasks
that are dependent on spatial working memory, defined as memory for
information relevant for a single trial (O'Neal et al., 1996; Daniel
et al., 1997; Fader et al., 1998, 1999; Bimonte and Denenberg, 1999;
Gibbs, 1999, 2000; Wilson et al., 1999).
The objective of the current experiments was to determine whether
estrogen regulates NMDA receptor binding in the hippocampus via its
ability to influence cholinergic neurotransmission. Additionally, we
determined whether the estradiol-induced increase in NMDA receptor binding was associated with enhancement in performance on a task of
working memory.
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MATERIALS AND METHODS |
Experiment 1
Subjects. Twenty-seven Long-Evans hooded
female rats, ~60 d of age, were purchased from Harlan Sprague Dawley
(Indianapolis, IN). Animal care was in accordance with guidelines set
by the National Institutes of Health Guide for the Care and Use
of Laboratory Animals (1996). Rats were housed individually in a
temperature-controlled vivarium under a 12 hr light/dark cycle (lights
on at 7:00 A.M.). At 65 d of age, all rats were ovariectomized
while under anesthesia induced by injection of ketamine (100 mg/kg,
i.p.; Bristol Laboratories, Syracuse, NY) and xylazine (7 mg/kg, i.p.;
Miles Laboratories, Shawnee, KS). Animals were randomly assigned to one
of the following groups (n = 9): (1) control, (2)
physostigmine at 0.0075 mg · kg 1 · hr1,
or (3) physostigmine at 0.06 mg · kg1 · hr1.
Treatments. Three days after ovariectomy, rats were
implanted subcutaneously with osmotic minipumps (Alza, Palo Alto, CA) containing physostigmine hemisulfate (Sigma, St. Louis, MO) in vehicle
solution (10% ethanol, 40% propylene glycol, and 50% distilled water) or sham pumps while under anesthesia induced by methoxyflurane (Pitman-Moore, Mundelein, IL). The physostigmine implants maintained constant delivery rates of 0.0075 or 0.06 mg · kg1 · hr1,
doses that approximated the ED50 and near-maximal
inhibition of cortical acetylcholinesterase activity, respectively
(Mandel et al., 1989). To coincide with the duration of estradiol
treatment demonstrated previously to increase NMDA receptor binding
(Woolley et al., 1997), implants were left in place for 3 d before
death by decapitation. Brains were rapidly removed, frozen on powdered dry ice, and stored at  70°C until sectioning.
Receptor autoradiography. Frozen coronal sections, 20 µm
thick, were cut on a microtome cryostat, thaw-mounted on gelatinized slides, and stored at 70°C. Twelve consecutive sections were taken
through the dorsal hippocampus of each brain, beginning at 2.56 mm
posterior to bregma and extending to 2.80 mm posterior to bregma
(Paxinos and Watson, 1998). NMDA receptor binding was determined
according to Weiland (1992a). Slide-mounted sections were thawed, dried
completely, and preincubated in slide mailers containing 10 ml of 50 mM Tris-acetate buffer (Sigma), pH 7.4, for 45 min at room temperature to remove endogenous ligand. Sections were
dried for 10 min under a stream of cool air. Six sections per brain
were incubated in slide mailers containing 200 nM
[3H]glutamate (51.90 Ci/mmol; NEN,
Boston, MA) in Tris-acetate buffer, and six alternate sections per
brain were incubated in Tris-acetate buffer containing 200 nM [3H]glutamate
plus 1 mM NMDA (Sigma). After incubation,
sections were rinsed four times for 5 sec each in ice-cold Tris-acetate buffer and dried rapidly. Sections were placed in contact with tritium-sensitive film (Hyperfilm; Amersham, Uppsala, Sweden) for
30 d with 3H-labeled plastic
standards (Microscales; Amersham) that contained known quantities of
radioactivity. Films were developed for 4 min in Kodak D-19 developer
and fixed for 5 min in Kodak rapid-fix.
Quantitative analysis of receptor binding. Autoradiograms
were analyzed by computer-assisted densitometry using NIH Image 1.61 software that measured relative optical density. The experimenter was
blind to treatment conditions during imaging procedures. Measurements were taken for the entire CA1 region of the dorsal hippocampus (Weiland, 1992a; Cyr et al., 2000), because estrogen treatment increases NMDA receptor binding in both the stratum radiatum and stratum oriens of CA1 (Woolley et al., 1997). Optical density was
converted to concentration of radioligand (picomoles per milligram of
protein) on the basis of a standard curve generated from
3H-labeled plastic standards. To determine
NMDA receptor binding, [3H]glutamate
binding that remained in the presence of NMDA was subtracted from total
[3H]glutamate binding. Previous work in
this laboratory revealed an asymmetric distribution of hippocampal
muscarinic receptors (Wolff et al., 1997). Therefore, to determine
whether a similar asymmetry in the distribution of NMDA receptors was
present, means were calculated for each hemisphere of each animal separately.
Experiment 2
Subjects. Forty Long-Evans female rats were obtained
at 60 d of age and ovariectomized at 65 d of age. Housing
conditions and surgical procedures were as described in Experiment 1. Animals were assigned to one of the following treatment groups
(n = 10): (1) control, (2) estrogen, (3) physostigmine,
or (4) physostigmine + BIBN 99.
Treatments. Three days after ovariectomy, rats assigned to
the physostigmine and the physostigmine + BIBN 99 groups were implanted subcutaneously with osmotic minipumps that maintained constant delivery
rates of physostigmine at 0.06 mg · kg1 · hr1,
the dose demonstrated in Experiment 1 to increase NMDA receptor binding
in CA1. Animals in the other two groups were implanted with sham pumps.
At the time that the minipumps were implanted, females assigned to the
physostigmine + BIBN 99 group received injections of the M2 muscarinic
receptor antagonist BIBN 99 (0.05 mg/kg, s.c.; provided by K. Thomae
GMBH, Biberach, Germany) delivered in 0.1 ml of 4.2% aqueous
D-mannitol solution. Additional injections of BIBN 99 were
given every 4 hr until animals were killed. This regimen of drug
treatment was based on observations that the behavioral effects of a
single injection of 0.05 mg/kg BIBN-99 are apparent for at least 4 hr
in rats (Quirion et al., 1995). Animals assigned to the other three
treatment groups received vehicle injections every 4 hr until death.
On days 3 and 4 after ovariectomy, animals assigned to the
estrogen group were injected intramuscularly with 10 µg (total dose)
of estradiol benzoate (Sigma) in 0.1 ml of cottonseed oil vehicle (Woolley et al., 1997). Animals assigned to the other three
groups were injected with oil vehicle alone. Forty-eight hours after
the second estradiol or oil vehicle injection, animals were killed by
decapitation. Brains were rapidly removed, frozen on powdered dry ice,
and stored at 70°C until sectioning. NMDA receptor binding in area
CA1 of the hippocampus was determined by quantitative receptor
autoradiography as described in Experiment 1.
Summary. The schedule of treatment procedures for each group
(control, estrogen, physostigmine, and physostigmine + BIBN 99) is
summarized in Table 1.
Experiment 3
The following experiment was completed and then replicated with
a separate set of animals. Data were combined for analyses.
Subjects. Forty Long-Evans hooded female rats were
purchased at 60 d of age. At 70 d of age, all rats were
placed on diets to maintain body weights at 90% of their free-feeding
weights. Animals were allowed to gain an additional 5 gm per week to
account for normal growth.
Training procedures. Females were trained to obtain food
rewards (Kellogg's Froot Loops) from the arms of an elevated eight-arm radial maze obtained commercially from Lafayette Instruments
(Lafayette, IN). The maze consisted of black metal floors and clear
Plexiglas walls. The eight arms (10 cm wide × 70 cm long × 20 cm high) were separated from an octagonal center compartment (33 cm
across) by guillotine doors that could be opened or closed silently by mechanical relay. The room in which the maze was located contained fixed extramaze cues. To begin each training trial, the rat was placed
in the center compartment of the maze with the doors of the arms
closed. All doors then were opened, and the rat was allowed to enter
any of the eight arms. The experimenter, who was seated in the room at
a fixed location ~5 feet from the maze, recorded arm choices. An arm
choice was scored if the rat traveled halfway down the length of an
arm. An error was scored if a rat reentered an arm visited previously.
The rat was allowed to choose arms in any order until all arms were
visited or until 5 min had elapsed. Beginning on the sixth training
trial, the animal was removed from the maze after it had made four
correct arm choices and placed in a holding cage for a period of 1 min.
It then was returned to the center compartment of the maze with all
arms opened and allowed to choose arms in any order until all arms were
visited or until a total of 6 min had elapsed. This training procedure was used to acclimate the animal to the test trial procedure, in which
a longer delay was instituted between the fourth and fifth arm choices.
Accuracy was scored by two measures, the number of correct choices
until the first error and the number of correct choices in the first
eight visits.
Rats were trained on the task for one trial per day for 18 d, at
which time all females had reached a criterion of 80% correct averaged
over three consecutive training trials. At that point, animals were
ovariectomized and randomly assigned to one of the following groups
(n = 9): (1) control, (2) estrogen, (3) estrogen + BIBN
99, or (4) BIBN 99. After ovariectomy, animals were trained on the maze
every other day until testing to maintain performance levels.
Treatments. On days 3 and 4 after ovariectomy, animals
assigned to the estrogen and the estrogen + BIBN 99 groups were
injected intramuscularly with 10 µg of estradiol benzoate in 0.1 ml
of cottonseed oil vehicle. Animals in the other two groups were
injected with 0.1 ml of vehicle alone. At the time of the first
injection of estradiol or oil, animals assigned to estrogen + BIBN 99 and to BIBN 99 were also injected with BIBN 99 (0.05 mg/kg, s.c.) delivered in 4.2% aqueous D-mannitol solution.
Animals in the other two groups were injected with vehicle alone.
Additional injections of BIBN 99 or vehicle were given every 4 hr until
testing. Approximately 48 hr after the second estradiol or oil
injection, animals were tested on the eight-arm radial maze.
Testing procedures. The test trial was conducted in a manner
identical to that of the training trials with one exception. After the
animal made four correct arm choices, it was removed from the maze and
placed in a holding cage for 3 hr. It then was returned to the maze to
complete the test trial.
Summary. The schedule of training, treatment, and testing
procedures for each group (control, estrogen, estrogen + BIBN 99, and
BIBN 99) is summarized in Table 2.
Experiment 4
Immediately after testing on the radial maze, rats from the
first replication of Experiment 3 were killed (n = 9),
and NMDA receptor binding in area CA1 of the dorsal hippocampus was
determined by quantitative receptor autoradiography as described in
Experiment 1.
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RESULTS |
Experiment 1
The goal of the first experiment was to determine whether
elevating endogenous levels of acetylcholine in ovariectomized rats via
administration of physostigmine, an acetylcholinesterase inhibitor, would increase NMDA receptor binding in CA1 of the hippocampus. Figures 1 and
2 illustrate that ovariectomized rats
receiving 3 d of treatment with physostigmine at 0.06 mg · kg1 · hr1,
a dose demonstrated to cause near-maximal inhibition of cortical acetylcholinesterase activity (Mandel et al., 1989), displayed increased NMDA receptor binding in CA1 of the hippocampus compared with
ovariectomized controls. To determine the effect of treatment as well
as to determine whether the effect of treatment varied across the
hemisphere, data collected from autoradiograms were analyzed by two-way
ANOVA (treatment × hemisphere). A significant main effect of
treatment was revealed (F(2,44) = 3.246; p < 0.05). Post hoc comparisons
indicated that animals that received physostigmine at 0.06 mg · kg1 · hr1,
but not those that received 0.0075 mg · kg1 · hr1,
displayed significantly higher NMDA receptor binding than did controls
(Newman-Keuls, p < 0.05). No effect of hemisphere or interaction of treatment and hemisphere was revealed.
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Figure 1.
Representative autoradiograms of
[3H]glutamate binding in the dorsal hippocampus in
brains taken from ovariectomized rats receiving control treatment
(A), 3 d of chronic treatment of
physostigmine at 0.0075 mg · kg1 · hr1
(B), or 3 d of chronic treatment of
physostigmine at 0.06 mg · kg1 · hr1
(C). Left panels illustrate total
[3H]glutamate binding, and right
panels illustrate [3H]glutamate binding
that remained in the presence of NMDA. NMDA binding was taken to be the
amount of total [3H]glutamate binding displaced by
NMDA (difference between left and right
panels). Arrows indicate the area in which
measurements were taken.
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Figure 2.
Effect of the acetylcholinesterase inhibitor
physostigmine on NMDA-displaceable [3H]glutamate
binding in CA1 of the dorsal hippocampus of ovariectomized rats.
Osmotic minipumps delivered physostigmine (PH)
for 3 d at constant rates of 0.0075 or 0.06 mg · kg1 · hr1. After
death, NMDA receptor binding was determined via in vitro
quantitative receptor autoradiography. Values reported are total
[3H]glutamate binding minus
[3H]glutamate binding in the presence of NMDA (in
pmol/mg protein ± SEM). Data were collected from 12 consecutive
sections of the dorsal hippocampus between 2.56 and 2.80 mm posterior
to bregma [*p < 0.05 vs control
(C); Newman-Keuls].
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Experiment 2
The results of Experiment 1 demonstrated that elevating
endogenous levels of acetylcholine in ovariectomized rats via
continuous administration of physostigmine for 3 d increased NMDA
receptor binding in CA1 of the hippocampus. The first objective of
Experiment 2 was to compare the effects of physostigmine and estrogen
on NMDA receptor binding. The second objective of Experiment 2 was to
determine whether acetylcholine acts at M2 muscarinic receptors to
increase NMDA binding in CA1. Specifically, we determined whether systemic administration of an M2 muscarinic receptor antagonist would
block the physostigmine-induced increase in NMDA receptor binding. The
M2 muscarinic antagonist
5,11-dihydro-8-chloro-11-[[4-[3-[(2,2-dimethyl-1-oxopentyl)ethylamino]propyl]-1-piperidinyl]acetyl]-6H-pyrido[2,3-b][1,4]benzodiazepin-6-one (BIBN 99), was used because it exhibits a high affinity for rat cardiac M2 sites (IC50, 30 nM) and a
low affinity for rat cortical M1 (IC50, 676 nM) and rat submandibular M3 (IC50,
690 nM) (Doods et al., 1993) sites. Figure
3 illustrates that ovariectomized rats
treated with either estrogen or physostigmine alone exhibited a
significant increase in NMDA receptor binding in CA1 of the hippocampus
compared with ovariectomized controls. Animals that were treated with
the M2 muscarinic receptor antagonist BIBN 99 along with physostigmine
did not exhibit this increase in NMDA receptor binding. Binding values
expressed in picomoles per milligram of protein were analyzed by
two-way ANOVA (treatment × hemisphere). There was a significant
main effect of treatment
(F(3,54) = 3.826; p < 0.02). Post hoc comparisons indicated
that animals that received either estrogen or physostigmine alone, but
not those that received physostigmine + BIBN 99, displayed
significantly higher NMDA receptor binding than did controls
(Newman-Keuls, p < 0.05). No effect of hemisphere or
interaction of hemisphere with treatment was found.
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Figure 3.
Effects of estrogen, physostigmine, and
physostigmine plus the M2 muscarinic receptor antagonist BIBN 99 on
NMDA-displaceable [3H]glutamate binding in CA1.
Ovariectomized rats received one of the following treatments: control
treatment (C), two injections of estradiol
benzoate (10 µg) delivered at 72 and 48 hr before death
(E), 3 d of continuous treatment of
physostigmine (0.06 mg · kg1 · hr1;
PH), or 3 d of continuous treatment of
physostigmine plus injections of BIBN 99 (0.05 mg/kg, delivered every 4 hr; PH + B). After death, NMDA receptor binding was
determined via in vitro quantitative receptor
autoradiography. Values reported are total
[3H]glutamate binding minus
[3H]glutamate binding in the presence of NMDA (in
pmol/mg protein ± SEM). Data were collected from 12 consecutive
sections of the dorsal hippocampus between 2.56 and 2.80 mm posterior
to bregma (*p < 0.05 vs C;
Newman-Keuls).
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Experiment 3
The first objective of Experiment 3 was to determine whether the
regimen of estradiol replacement demonstrated previously to induce
formation of new dendritic spines (Gould et al., 1990; Woolley et al.,
1997) and to increase NMDA receptor binding in CA1 (see Results of
Experiment 2) (see also Woolley et al., 1997) would enhance performance
on a task of working memory. The second objective was to determine
whether an estradiol-induced enhancement of working memory was mediated
by the action of acetylcholine on M2 receptors. Specifically, the
effects of systemic injections of estradiol given to ovariectomized
rats 72 and 48 hr before testing on an eight-arm radial maze were
assessed, and it was determined whether chronic administration of BIBN
99, an M2 antagonist, would counteract the effects of estradiol on
working memory performance. Figure
4A illustrates that
ovariectomized rats treated with two injections of estradiol 72 and 48 hr before testing displayed enhanced working memory performance on the
eight-arm radial maze compared with estradiol-treated animals also
treated with BIBN 99, animals treated with BIBN 99 alone, and
ovariectomized controls. Choice accuracy data collected on the test
trial were analyzed by a one-way ANOVA (treatment) followed by
post hoc comparisons. There was a significant main effect of
treatment (F(3,64) = 7.752; p < 0.01), for the number of correct choices until the
first error (Fig. 4A). Animals treated with estradiol
alone made significantly more correct arm choices until the first error
than did animals treated with estradiol + BIBN 99, animals treated with
BIBN 99 alone, or control animals (Newman-Keuls, p < 0.05). There was also a significant main effect of treatment
(F(3,64) = 2.910; p < 0.01), for the number correct in the first eight visits (Fig. 4B). Animals treated with estradiol alone made
significantly more correct arm choices in the first eight visits than
did animals treated with BIBN 99 alone (Newman-Keuls,
p < 0.05). However, no other significant group
differences were revealed for this measure of arm-choice accuracy.
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Figure 4.
Effects of estrogen, estrogen plus the M2 receptor
antagonist BIBN 99, or BIBN 99 alone on working memory performance in
an eight-arm radial maze. Female rats were trained to obtain food
rewards from the arms of the maze with all arms baited. For the
training trials, a 1 min delay was instituted between the fourth and
fifth arm choices. After 18 d of training, all rats were
ovariectomized and randomly assigned to receive one of the following
treatments: control treatment (C), two injections
of estradiol benzoate (10 µg) delivered 72 and 48 hr before death
(E), two injections of estradiol benzoate plus
injections of BIBN 99 (0.05 mg/kg, delivered every 4 hr; E + B), or injections of BIBN 99 alone (B).
Two separate replications of the experiment were completed, and data
were combined for analyses. Data presented are from the test trial in
which a 3 hr delay was instituted between the fourth and fifth arm
choices. A, Mean number of correct arm choices (±SEM)
before the first error (*p < 0.05 vs
C, E + B, B;
Newman-Keuls). B, Mean number of correct arm choices
(±SEM) in the first eight visits (**p < 0.05 vs
B; Newman-Keuls).
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Experiment 4
In Experiment 4, NMDA receptor binding was measured in brains
taken from rats used in behavior testing in Experiment 3. The objective
of Experiment 4 was to determine whether acetylcholine mediates the
estradiol-induced increase in NMDA receptor binding by acting at M2
receptors. Therefore, it was determined whether administration of BIBN
99, the M2 antagonist, would block the estradiol-induced increase in
NMDA receptor binding in CA1 of the hippocampus. Additionally, it was
determined whether BIBN 99 administered alone would affect NMDA
receptor binding in CA1. Figure 5
illustrates that ovariectomized rats treated with estrogen exhibited a
significant increase in NMDA receptor binding in CA1 of the hippocampus
compared with estradiol-treated animals that also were treated with
BIBN 99 and ovariectomized controls. Data collected from autoradiograms
were analyzed by two-way ANOVA (treatment × hemisphere). A
significant main effect of treatment was revealed (F(3,56) = 3.559; p < 0.02). Post hoc comparisons revealed that females that
received estrogen alone displayed significantly higher NMDA receptor
binding than did control animals and those that were treated with
estrogen and BIBN 99 (Newman-Keuls, p < 0.05). There
was no significant effect of hemisphere and no interaction of
hemisphere and treatment.
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Figure 5.
Effects of estrogen, estrogen plus the M2 receptor
antagonist BIBN 99, or BIBN 99 alone on NMDA-displaceable
[3H]glutamate binding in CA1. Ovariectomized rats
received one of the following treatments: control treatment
(C), two injections of estradiol benzoate (10 µg) delivered 48 and 72 hr before death (E),
two injections of estradiol benzoate plus injections of BIBN 99 (0.05 mg/kg, delivered every 4 hr; E + B), or injections of
BIBN 99 alone (B). After death, NMDA receptor
binding was determined via in vitro quantitative
receptor autoradiography. Values reported are total
[3H]glutamate binding minus
[3H]glutamate binding in the presence of NMDA (in
pmol/mg protein ± SEM). Data were collected from 12 consecutive
sections of the dorsal hippocampus between 2.56 and 2.80 mm posterior
to bregma (*p < 0.05 vs C, E + B; Newman-Keuls).
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DISCUSSION |
The results of the present experiments indicate that
acetylcholine, acting at M2 muscarinic receptors, plays a role in the estradiol-induced increase in NMDA receptor binding in CA1 of the
dorsal hippocampus as well as in the associated enhancement of
performance on a working memory task. In Experiment 1, elevating endogenous levels of acetylcholine in ovariectomized rats by continuous administration of physostigmine, an acetylcholinesterase inhibitor, increased NMDA receptor binding in CA1. In Experiment 2, it was further
shown that the increase in NMDA receptor binding in CA1 induced by
physostigmine was comparable with the increase induced by estrogen.
Additionally, the administration of BIBN 99, an M2 muscarinic receptor
antagonist, prevented the increase in NMDA receptor binding induced by
physostigmine. In Experiment 3, the regimen of estradiol replacement
shown to increase NMDA receptor binding in CA1 also enhanced working
memory performance as assessed in an eight-arm radial maze. In
addition, this estradiol-induced enhancement in performance was blocked
by administration of BIBN 99. Finally, in Experiment 4, estrogen
treatment increased NMDA receptor binding in CA1 in brains taken from
animals immediately after maze testing in Experiment 3, an increase
that was prevented by systemic administration of BIBN 99.
The present results demonstrate that the ability of estrogen to effect
change in NMDA receptor binding in CA1 is related to its ability to
alter cholinergic neurochemistry. In a previous report, the muscarinic
receptor antagonist scopolamine failed to block the estradiol-induced
increase in spine density in ovariectomized rats (Woolley and McEwen,
1994). However, in that experiment scopolamine was administered every
12 hr. Because scopolamine has a half-life of <30 min in rats (Lyeth
et al., 1992), it may have been unable to block muscarinic receptors
during a significant portion of the period of estrogen exposure. In the
present study, continuous release of physostigmine mimicked the effect
of estradiol on levels of NMDA receptor binding in CA1, an effect that
was demonstrated across two experiments.
The results of the current experiments indicate that acetylcholine acts
at the M2 subtype of the muscarinic receptor to affect levels of NMDA
receptor binding in CA1. Although the specific mechanisms by which
increased levels of acetylcholine act at M2 muscarinic receptors to
increase NMDA receptor binding cannot be determined from the results of
the present experiments, there are interesting possibilities.
Cholinergic neurons in the medial septal/diagonal band complex contain
estrogen receptors (Shughrue et al., 2000). Estrogen could act on these
receptors to increase acetylcholine release in projection sites in the
hippocampus. Increased levels of acetylcholine could act at M2
muscarinic receptors located on the axon terminals of GABAergic basket
cells located in the pyramidal cell layer of Ammon's horn (Freund and
Gulyas, 1997; Hajos et al., 1998). These GABA interneurons provide
powerful somatic inhibition to hippocampal pyramidal cells. The action of acetylcholine at the M2 receptors is to inhibit the release of GABA.
Thus, an estradiol-induced increase in levels of acetylcholine would
increase action at these M2 receptors, resulting in increased inhibition of GABA release leading to disinhibition of the pyramidal cells, a step demonstrated to lead to morphological changes in CA1
(Murphy and Segal, 1997).
As an alternative, but not mutually exclusive, hypothesis, increased
levels of acetylcholine induced by physostigmine or estrogen could act
at M2 receptors located in the medial septal region and diagonal band
complex, resulting in disinhibition of pyramidal cells of the
hippocampus. In the basal forebrain, the M2 subtype of the muscarinic
receptor is localized to dendrites and somata of noncholinergic
neurons, at least some of which contribute to the GABAergic component
of the septohippocampal pathway (Levey et al., 1995). GABAergic input
from the septum, by exclusively targeting GABA interneurons in the
hippocampus, regulates GABAergic inhibition of hippocampal principal
cells (Freund and Antal, 1988). Locally released acetylcholine in the
medial septal/diagonal band complex provides a strong excitatory drive
to GABA neurons in the septohippocampal pathway (Alreja et al., 2000).
In the present study, elevating endogenous levels of acetylcholine via
systemic administration of estradiol or physostigmine most likely
stimulated M2 receptors in the basal forebrain, resulting in increased
excitation in the GABAergic inputs to the hippocampus. The resultant
inhibition of hippocampal GABA interneurons would contribute to
disinhibition of the pyramidal cells. Blocking the M2 muscarinic
receptors in the medial septal region and diagonal band complex could,
at least partly, be responsible for the ability of BIBN 99 to
counteract the effects of physostigmine and estradiol on CA1 NMDA
receptor binding. Clearly, further work is needed to identify the
specific mechanisms by which acetylcholine acts at the M2 subtype of
the muscarinic receptor to increase NMDA receptor binding in CA1 of the
hippocampus. In addition, it is important to note that it is currently
unknown whether the mechanism by which estrogen increases CA1 NMDA
receptor binding is the same as the mechanism by which estrogen induces
parallel increases in CA1 dendritic spine and synapse density (Gould et
al., 1990; Woolley et al., 1997). Furthermore, although acetylcholine
acts at M2 receptors to increase NMDA receptor binding in CA1, the
possible increases in spine and synapse density of CA1 pyramidal cells
induced by acetylcholine have not been investigated.
Although the present results indicate that estrogen interacts with the
cholinergic system to increase NMDA binding in CA1, estrogen could also
act via other mechanisms to influence NMDA receptor binding as well as
spine and synapse density. For example, estrogen may act directly on
hippocampal GABAergic interneurons to inhibit GABA activity and thus
increase the excitatory drive on pyramidal cells, leading to
morphological change in CA1 (Murphy et al., 1998). Immunoreactivity for
the classical estrogen receptor (ER- ) is expressed in GABAergic
interneurons in the rat hippocampus (Weiland et al., 1997). In the
dorsal hippocampus, levels of ER- immunoreactivity were greatest in
the dentate gyrus and stratum radiatum of CA1, although these levels
were low in comparison with those of other brain regions such as the
hypothalamus. Interestingly, in spite of the ability of estradiol to
induce changes in GAD mRNA in the pyramidal cell layer of CA1 (Weiland,
1992b), there were few ER- immunoreactive cells located in that
region. However, results of an in situ hybridization study
revealed that in addition to ER- mRNA, the newly cloned estrogen
receptor- (ER-) mRNA is also expressed in the hippocampus. In
recent autoradiographic studies, binding sites for
125I-estrogen, a ligand with a similar
affinity for both ER- and ER-, were localized in the pyramidal
cells of CA1-CA3, with the highest levels of binding in the ventral
portion of CA2 and CA3 (Shughrue et al., 1997; Shughrue and
Merchenthaler, 2000). The roles of ER- and ER- in the regulation
of GABAergic synapses have yet to be determined.
An important finding of the experiments in the present study is that
the changes in NMDA receptor binding in CA1 after acute estrogen
treatment were associated with an enhancement in working memory
performance in an eight-arm radial maze. In addition, the M2 muscarinic
receptor antagonist BIBN 99 was able to counteract the estrogen-induced
enhancement in working memory performance. In a previous study, no
differences in working memory performance during the acquisition of an
eight-arm radial maze were found across the estrous cycle (Stackman et
al., 1997). Taken together, these results indicate that the increase in
spine and synapse density and the associated increase in NMDA receptor
binding that occurs as a result of acute estrogen replacement may
contribute to improvements in working memory performance in
ovariectomized rats. It remains to be determined whether increases in
spine and synapse density and NMDA receptor binding in CA1 are
associated with improvements in working memory performance that have
been demonstrated to occur after a regimen of chronic estrogen
replacement (Daniel et al., 1997; Luine et al., 1998; Gibbs, 1999,
2000).
Although not directly related to the objectives of the present study,
these results provide information as to the effect of an M2 muscarinic
receptor antagonist on learning and memory performance. In previous
studies, administration of BIBN 99 improved performance on a reference
memory task in the Morris water maze in aged memory-impaired (Quirion
et al., 1995) and traumatic brain-injured rats (Pike and Hamm, 1995).
In contrast, on a task of working memory in a T maze, intrahippocampal
administration of the putative M2 antagonist gallamine impaired
performance (Messer and Miller, 1988). In the present study, there was
not a significant difference in working memory performance between
ovariectomized rats treated with BIBN 99 and ovariectomized controls.
However, ovariectomized rats treated with estrogen significantly
outperformed ovariectomized rats treated with BIBN 99 on a working
memory task in the radial arm maze.
In conclusion, the results of the present experiments suggest for the
first time a mechanism by which elevated levels of estrogen can lead to
increased levels of NMDA receptor binding in CA1 of the hippocampus.
Specifically, our results indicate that acetylcholine acts at the M2
subtype of the muscarinic receptor to mediate the estradiol-induced
increase in NMDA receptor binding. Importantly, these results also
demonstrate that the estradiol-induced increase in NMDA receptor
binding is associated with enhancement in working memory performance in
an eight-arm radial maze.
| |
FOOTNOTES |
Received April 17, 2001; revised June 18, 2001; accepted June 19, 2001.
This research was supported by National Science Foundation Award
IBN-9728901 (G.P.D.). We thank Jeffrey Puissegur and Ray Berryman for
excellent animal husbandry, Zuzana Hruska for imaging assistance, and
Drs. Paul Colombo, Jeffrey Tasker, and Beth Wee for helpful discussions
throughout the course of this study.
Correspondence should be addressed to Dr. Jill Daniel,
Department of Pharmacology and Experimental Therapeutics, Louisiana State University Health Sciences Center, 1901 Perdido Street, New
Orleans, LA 70112. E-mail: jdanie2{at}lsuhsc.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
