 |
 Previous Article | Next Article 
The Journal of Neuroscience, August 15, 2000, 20(16):5924-5931
Coactivation of  -Adrenergic and Cholinergic Receptors Enhances
the Induction of Long-Term Potentiation and Synergistically Activates
Mitogen-Activated Protein Kinase in the Hippocampal CA1 Region
Ayako M.
Watabe1,
Paulette A.
Zaki2, and
Thomas J.
O'Dell1
1 Department of Physiology, University of California,
Los Angeles School of Medicine and 2 Interdepartmental PhD
Program for Neuroscience, University of California, Los Angeles, Los
Angeles, California 90095
 |
ABSTRACT |
Interactions between noradrenergic and cholinergic receptor
signaling may be important in some forms of learning. To
investigate whether noradrenergic and cholinergic receptor interactions
regulate forms of synaptic plasticity thought to be involved in memory formation, we examined the effects of concurrent  -adrenergic and
cholinergic receptor activation on the induction of long-term potentiation (LTP) in the hippocampal CA1 region. Low concentrations of
the -adrenergic receptor agonist isoproterenol (ISO) and the cholinergic receptor agonist carbachol had no effect on the induction of LTP by a brief train of 5 Hz stimulation when applied individually but dramatically facilitated LTP induction when coapplied. Although carbachol did not enhance ISO-induced increases in cAMP, coapplication of ISO and carbachol synergistically activated p42 mitogen-activated protein kinase (p42 MAPK). This suggests that concurrent -adrenergic and cholinergic receptor activation enhances LTP induction by activating MAPK and not by additive or synergistic effects on adenylyl
cyclase. Consistent with this, blocking MAPK activation with MEK
inhibitors suppressed the facilitation of LTP induction produced by
concurrent -adrenergic and cholinergic receptor activation. Although
MEK inhibitors also suppressed the induction of LTP by a stronger 5 Hz
stimulation protocol that induced LTP in the absence of ISO and
carbachol, they had no effect on LTP induced by high-frequency synaptic
stimulation or low-frequency synaptic stimulation paired with
postsynaptic depolarization. Our results indicate that MAPK activation
has an important, modulatory role in the induction of LTP and suggest
that coactivation of noradrenergic and cholinergic receptors regulates
LTP induction via convergent effects on MAPK.
Key words:
long-term potentiation; -adrenergic receptors; cholinergic receptors; adenylyl cyclase; mitogen-activated protein
kinase; hippocampus
| |
INTRODUCTION |
Numerous behavioral studies indicate
that noradrenergic and cholinergic systems in the brain are involved in
learning and memory (for review, see McGaugh, 1989 ; Blokland, 1996;
Jerusalinsky et al., 1997) and that interactions between these two
neurotransmitters may be important for some forms of learning (Decker
et al., 1990; Decker and McGaugh, 1991; Ohno et al., 1997). Although
norepinephrine and acetylcholine potentially could modulate
memory formation via multiple effects occurring at different levels of
CNS function, one possibility is that they act and interact at the
cellular level to regulate activity-dependent changes in synaptic
strength, such as long-term potentiation (LTP), that are thought to be
involved in the storage of new information during learning (Izquierdo
and Medina, 1995). Indeed, whereas the induction of LTP at excitatory synapses in the CA1 region of the hippocampus is primarily dependent on
activation of NMDA-type glutamate receptors (Bliss and Collingridge, 1993), noradrenergic (Sah and Bekkers, 1996; Thomas et al., 1996; Katsuki et al., 1997; Izumi and Zorumski, 1999) and cholinergic (Blitzer et al., 1990; Huerta and Lisman, 1993) receptor activation strongly enhances the induction of LTP by some patterns of synaptic stimulation. Moreover, coactivation of these receptors
synergistically enhances the induction of LTP in rat visual cortex
(Brocher et al., 1992).
The cellular mechanisms responsible for the effects of concurrent
noradrenergic and cholinergic receptor action on LTP induction are
mainly unknown. One possibility is that coactivation of noradrenergic and cholinergic receptors modulates LTP induction via synergistic or
additive effects on neuronal excitability that enhance NMDA receptor
activation during synaptic activity (Brocher et al., 1992).
Alternatively, coactivation of these receptors might influence LTP
induction by modulating components of the LTP pathway that lie
downstream of NMDA receptor activation. For instance, the induction of
LTP by some patterns of synaptic stimulation requires a protein kinase
A (PKA)-dependent suppression of protein phosphatases (Blitzer et al.,
1995, 1998; Thomas et al., 1996), and coactivation of noradrenergic and
muscarinic receptors thus might enhance LTP induction via synergistic
or additive effects on adenylyl cyclase activity (Baumgold, 1992).
Noradrenergic and cholinergic receptor agonists also activate the
mitogen-activated protein kinase (MAPK) signaling cascade in
hippocampal neurons (Roberson et al., 1999), whereas inhibitors of MAPK
activation suppress LTP induction (English and Sweatt, 1997; Atkins et
al., 1998; Coogan et al., 1999; Winder et al., 1999; Rosenblum et al.,
2000). Thus, another possibility is that noradrenergic and cholinergic
receptor signaling pathways modulate LTP induction via effects on MAPK.
To investigate the potential role of adenylyl cyclase and MAPK
signaling in the noradrenergic and cholinergic modulation of LTP
induction, we examined the effects of -adrenergic and cholinergic receptor agonists on cAMP levels, MAPK activation, and LTP induction in
the hippocampal CA1 region. Our results show that coactivation of
-adrenergic and cholinergic receptors facilitates the induction of
LTP in a highly cooperative manner and suggest that coactivation of
noradrenergic and cholinergic receptors regulates LTP induction via a
synergistic activation of MAPK.
| |
MATERIALS AND METHODS |
Slice preparation and electrophysiology. Hippocampal
slices used in both electrophysiological and biochemical experiments were obtained from 4- to 7-week-old male C57BL/6 mice. Animals were
anesthetized with halothane and killed by cervical dislocation; then the brains were removed rapidly and placed in cold (4°C) artificial CSF (aCSF) consisting of (in mM) 124
NaCl, 4.4 KCl, 25 NaHCO3, 1.0 NaH2PO4, 1.2 MgSO4, 2.0 CaCl2, and 10 glucose (gassed with 95% O2/5%
CO2). Transverse slices (400 µm thick) were
prepared by using standard techniques and then were transferred to an
interface-type recording chamber (Fine Science Tools, Foster City, CA)
where they were perfused continuously (1-3 ml/min) with warm (30°C) aCSF for at least 1 hr before electrophysiological experiments. Longer
recovery times were used in the biochemical experiments (see below).
A bipolar, nichrome wire stimulating electrode placed in stratum
radiatum of the CA1 region of the slice was used to activate Schaffer
collateral/commissural fiber synapses onto CA1 pyramidal cells. In
extracellular recording experiments the field EPSPs (fEPSPs) evoked by
0.02 Hz presynaptic fiber stimulation were recorded by using an
aCSF-filled glass microelectrode placed in stratum radiatum (electrode
resistance ranged from 5 to 10 M ). At the start of an experiment we
determined the maximal fEPSP amplitude that could be generated in each
slice and then set the intensity of presynaptic fiber stimulation to
evoke baseline fEPSPs that were ~50% of the maximal fEPSP amplitude.
In some experiments whole-cell current-clamp recordings were used to
record EPSPs from CA1 pyramidal cells in slices maintained in submerged
slice recording chambers. Slices (with the CA3 region removed) were
bathed in a modified aCSF containing elevated levels of
CaCl2 and MgSO4 (4 mM each), reduced levels of KCl (2.2 mM), and
100 µM picrotoxin. Patch-clamp electrodes were fabricated from 1.5 mM outer diameter borosilicate glass and filled
with a solution containing (in mM) 122.5 Cs-gluconate, 0.9 CsCl, 10 tetraethylammonium chloride (TEA-Cl), 0.2 EGTA, 2 Mg-ATP, 0.3 GTP, 10 HEPES, and 0.2% dimethylsulfoxide (DMSO), pH 7.2 (osmolarity, 290-295 mOsm; electrode resistance, 2.5-5.0 M). A modified
electrode-filling solution containing an elevated concentration of CsCl
(17.5 mM) and no DMSO was used in experiments in which MEK
inhibitors were bath-applied. Current injected through the recording
electrode was used to hyperpolarize cells to between  80 and 85 mV,
and 50-msec-long pulses of hyperpolarizing current (100 pA) were
delivered once every 20 sec to monitor access and input resistance.
Only cells with resting membrane potentials more negative than 60 mV
and an input resistance >140 M were used. Access resistances, determined from the bridge balance circuit of the intracellular amplifiers (Dagan IX2-700, Axon Instruments Axoprobe 1A, Foster City,
CA), ranged from 15 to 34 M. At the start of each experiment the
intensity of presynaptic stimulation was adjusted to evoke postsynaptic
EPSPs between 4 and 7 mV in amplitude (stimulation rate, 0.05 Hz). To
induce LTP, we paired 100 EPSPs evoked at 2 Hz with a constant
injection of current through the recording electrode to depolarize the
postsynaptic membrane potential to between 0 and +20 mV. Whole-cell
recordings were maintained for 17-20 min before we attempted to induce LTP.
Data acquisition and analysis were performed with programs written with
the Experimenter's Workbench and Common Processing software package
(Data Wave Technologies). All values are reported as mean ± SEM.
Synaptic responses were normalized to average values measured over a
baseline period that was recorded before any experimental manipulation.
The average size of EPSPs (obtained from measurements of the slope)
recorded between 40 and 45 min after 5 Hz stimulation (in extracellular
recordings) or 25-30 min after pairing EPSPs with low-frequency
stimulation (in intracellular recordings) was used for statistical
comparisons (paired and unpaired Student's t tests or
ANOVAs, followed by Dunnett's test comparisons with control). Complex
spike bursting during 5 Hz stimulation was determined by visually
inspecting each synaptic response during the 5 Hz train and counting
the number of negative spikes evoked by each EPSP (see Thomas et al.,
1998).
cAMP assay. Hippocampal slices from the same animal were
maintained in the same interface chambers as those used for
electrophysiological experiments and were allowed to recover for at
least 2 hr. Slices (two at a time) then either were left untreated
(control slices) or were exposed to a 10 min bath application of 200 nM isoproterenol (ISO), 200 nM carbachol, or
ISO plus carbachol (200 nM each). At the end of each
treatment the slices were removed rapidly from the chamber and
immediately homogenized in ice-cold 3% perchloric acid (PCA). The pH
of the samples was neutralized with 15% KHCO3 and, after centrifugation (5 min at 16,000 × g) the
supernatants were assayed for cAMP by using a commercially available
kit (Diagnostic Products, Los Angeles, CA). cAMP levels
were normalized to the amount of protein in the PCA pellet that was
determined with a modified Lowry assay (Sigma, St. Louis, MO)
(Peterson, 1977).
Protein preparations and Western immunoblotting analysis. To
examine the effects of -adrenergic and cholinergic receptor activation on MAPK activation, we allowed hippocampal slices from the
same animal to recover for 3-4 hr and then either left them untreated
(control slices) or exposed them to 10 min bath applications of ISO
alone, carbachol alone, or ISO plus carbachol. Then the slices (two to
three in each treatment condition) were frozen quickly on a glass plate
on dry ice, and the CA1 regions were isolated by microdissection. The
isolated CA1 regions were transferred to a microcentrifuge tube kept in
a dry ice/ethanol bath and subsequently were homogenized by sonication
(Micron Ultrasonic Cell Disruptor) in 90 µl of an ice-cold lysis
buffer containing (in mM) 50 Tris-HCl, pH 7.5, 50 NaCl, 10 EGTA, 10 EDTA, 5 sodium pyrophosphate, 1 sodium orthovanadate, 4 para-nitrophenyl phosphate, and 1 phenylmethylsulfonyl fluoride plus 20 µg/ml of leupeptin, 4 µg/ml of aprotinin, and 0.01% Triton X-100. After centrifugation at 12,000 × g (for 5 min at 4°C) aliquots of the supernatant were
saved for protein determination, and denaturing loading buffer [0.5
M Tris-HCl, pH 6.8, 4.4% (w/v) SDS, 20% (v/v)
glycerol, 2% -mercaptoethanol, and bromophenol blue] was added
immediately to the rest of the sample. Protein concentrations were
determined by using a Bio-Rad Protein Assay Kit (Hercules, CA) based on
the Bradford method (Bradford, 1976).
Samples containing equivalent amounts of protein (15-40 µg) were
boiled for 3 min, separated on 12% SDS-PAGE gels, transferred onto
nitrocellulose membranes, and blocked for 3 hr in 5% dry milk in PBS
with 0.05% Tween-20 (1 µM microcystin LR was also included for phospho-MAPK blots). Then the blots were incubated overnight with an antiserum that specifically recognizes the Thr202 and
Tyr204 dually phosphorylated, activated forms of p42/p44 MAPK (1:2000;
New England Biolabs, Beverly, MA). Another antibody that recognizes
both phosphorylated and unphosphorylated forms of p42/p44 MAPK (1:1000;
New England Biolabs) was used to measure total MAPK levels. After three
washes (for 10 min each) with PBS containing 0.05% Tween-20, the blots
were incubated with horseradish peroxidase-conjugated secondary
antibodies for 2 hr. Protein signals were visualized with enhanced
chemiluminescence (ECL Western Blotting Analysis system, Amersham,
Arlington Heights, IL) and quantified with a Molecular Dynamics
Personal Densitometer SI with ImageQuaNT software (Molecular Dynamics,
Sunnyvale, CA). Digital resolution was set at 12 bits per pixel (50 µm pixel size), and areas from a single experiment (untreated control
slices plus slices treated with ISO, carbachol, and ISO plus carbachol;
all slices from the same animal) were scanned as a single data set.
Western blots were developed to be in a linear range for densitometry.
For each experiment both total MAPK and phospho-MAPK levels were
normalized relative to that seen in untreated, control slices. ANOVAs
followed by Dunnett's test comparisons to untreated control groups
were used to determine statistical significance in all biochemical assays.
Materials. Salts in the aCSF were from Sigma.
R()-isoproterenol (+)-bitartrate, carbachol, and atropine
were purchased from Research Biochemicals (RBI, Natick, MA). The MEK
inhibitors U0126 and PD98059 were obtained from Promega (Madison, WI)
and New England Biolabs, respectively. SL327 was a generous gift from
DuPont Pharmaceuticals (Wilmington, DE). All three MEK inhibitors were
prepared as concentrated stock solutions in DMSO and then diluted into
aCSF before each experiment (maximal final DMSO concentration, 0.33%).
Slices were pretreated with MEK inhibitors for at least 60 min before
we attempted to induce LTP, and the inhibitors remained in the bath for
the duration of the experiment. In experiments investigating the
effects of U0126 and PD98059, aCSF containing the inhibitors (117-133 ml total volume) was recycled through the recording chambers (no more
than twice) during the course of an experiment. Interleaved vehicle
control experiments (0.2% and 0.33% DMSO) were performed in the same manner.
| |
RESULTS |
Coactivation of cholinergic and -adrenergic receptors
enables the induction of LTP by short trains of 5 Hz stimulation
To examine the potential role of -adrenergic and cholinergic
receptor interactions in the induction of LTP, we examined the effects
of ISO and carbachol on the induction of LTP by a 5-sec-long train of 5 Hz stimulation that by itself induced only a small potentiation of
synaptic transmission (Fig.
1A). The amount of LTP
induced by 5 Hz stimulation was not enhanced when 5 Hz stimulation was
delivered at the end of a 10 min bath application of either 200 nM ISO or 200 nM carbachol
alone (Fig. 1B), indicating that the induction of LTP
is not modulated significantly by relatively low levels of
-adrenergic or cholinergic receptor activation. In contrast, the
induction of LTP by 5 Hz stimulation was facilitated dramatically when
-adrenergic and cholinergic receptors were coactivated by a 10 min
bath application of aCSF containing both ISO and carbachol (200 nM each; Fig. 1A,B). In control
experiments we found that a 10 min bath application of ISO and
carbachol by itself (no 5 Hz stimulation) had no lasting effect on
synaptic transmission (n = 3; data not shown). Thus,
the potentiation induced by 5 Hz stimulation in the presence of ISO
plus carbachol is not attributable to an activity-independent
enhancement of synaptic transmission induced by coactivation of
-adrenergic and cholinergic receptors. The induction of LTP by 5 Hz
stimulation in the presence of ISO plus carbachol was blocked
significantly, however, by the NMDA receptor antagonist
2-amino-5-phosphonovaleric acid (D,L-APV, 100 µM; fEPSPs were 114.4 ± 10.8% of baseline after 5 Hz stimulation; n = 5),
suggesting that coactivation of -adrenergic and cholinergic receptors facilitates the induction of NMDA receptor-dependent LTP.
Finally, the muscarinic receptor antagonist atropine (50 µM) completely blocked the enhancement of LTP
induction by coapplication of ISO plus carbachol (n = 3; data not shown), indicating that the effects of carbachol are
attributable to muscarinic receptor activation.
View larger version (19K):
[in this window]
[in a new window]
|
Figure 1.
Coactivation of -adrenergic and cholinergic
receptors enhances the induction of LTP by a short train of 5 Hz
stimulation. A, A 5 sec train of 5 Hz stimulation
(delivered at time 0) by itself induced only a small
potentiation of synaptic transmission (open symbols;
fEPSPs potentiated to 120.5 ± 7.12% of baseline;
n = 6; p < 0.05, paired
t test comparison to pre-5 Hz baseline) but induced
robust LTP (filled symbols; fEPSPs potentiated to
175.6 ± 11.2% of baseline; n = 6) when
delivered at the end of a 10 min bath application of ISO plus carbachol
(CCh) (200 nM each; presence in bath
indicated by the bar). Traces show fEPSPs
recorded during baseline and 45 min after 5 Hz stimulation in a control
experiment (5 Hz stimulation alone, left
traces) and in an experiment in which 5 Hz stimulation
was delivered in the presence of ISO plus carbachol (right
traces). Calibration: 2 mV, 5 msec. B, Summary
of the effects of 5 Hz stimulation on synaptic strength when 5 Hz
stimulation was delivered alone (open bars; data from
the experiment shown in A) or at the end of a 10 min
application of ISO (n = 6), carbachol
(n = 6), or ISO plus carbachol (data from the
experiment shown in A). Although coapplication of ISO
plus carbachol significantly enhances the amount of LTP induced by 5 Hz
stimulation (*p < 0.05), neither ISO alone nor
carbachol alone significantly enhances LTP induction (fEPSPs were
potentiated to 125.4 ± 7.9% and 112.9 ± 4.1% of baseline,
respectively).
|
|
Carbachol modulation of ISO-induced increases in cAMP does not
account for the enhancement of LTP induction by coactivation of
-adrenergic and cholinergic receptors
Although a low concentration of ISO alone failed to enhance the
induction of LTP by 5 sec of the 5 Hz stimulation, we found that the
amount of potentiation induced by 5 Hz stimulation was increased
significantly by a higher concentration of ISO (1.0 µM;
n = 7; data not shown). This suggests that stronger
activation of Gs-linked -adrenergic receptors
alone, and by extension larger increases in cellular levels of cAMP,
can enhance the induction of LTP by a brief train of 5 Hz stimulation.
The diverse regulation of different adenylyl cyclase isoforms by
increases in intracellular Ca2+, G-protein
 subunits, and protein kinase C phosphorylation as well as
 s subunits of heterotrimeric G-proteins (for
review, see Cooper et al., 1995; Mons and Cooper, 1995) provides a
number of potential signaling pathways through which coactivation of Gs-coupled -adrenergic and
Gq/Gi/o-coupled muscarinic
receptors might activate adenylyl cyclase synergistically (Baumgold,
1992). We thus investigated whether coapplication of ISO and carbachol might facilitate the induction of LTP by 5 Hz stimulation via additive
or synergistic effects on adenylyl cyclase activity. In these
experiments we measured cAMP levels in hippocampal slices that either
were untreated or were exposed to 10 min bath applications of 200 nM ISO alone, 200 nM
carbachol alone, or a combination of ISO plus carbachol (Fig.
2). Compared with basal levels measured in untreated control slices, cAMP levels were increased significantly in slices exposed to ISO (levels were 159 ± 17.1% of that
measured in control slices; n = 5). In contrast, cAMP
levels were not elevated significantly in slices treated with carbachol
alone (cAMP levels were 106 ± 9.1% of control; n = 5). Carbachol also had no significant effect on ISO-induced increases
in cAMP (cAMP levels in slices simultaneously exposed to both carbachol
and ISO were 152.6 ± 19.9% of control; n = 5).
In control experiments we found that a 10 min application of the
adenylyl cyclase activator forskolin (50 µM)
induced a more than sevenfold increase in cAMP levels (cAMP levels in
forskolin-treated slices were 799 ± 39.2% of control; n = 4). This indicates that 200 nM ISO does not induce a saturating level of
adenylyl cyclase activation that masks a modulatory effect of carbachol
on ISO-induced increases in cAMP. On the basis of these observations it
seems unlikely that coactivation of cholinergic and -adrenergic
receptors facilitates the induction of LTP by 5 Hz stimulation via
additive or synergistic effects on cAMP production.
View larger version (12K):
[in this window]
[in a new window]
|
Figure 2.
Carbachol does not modulate ISO-induced increases
in cAMP. The histogram shows average ± SEM cAMP levels (in
picomoles per milligram of protein) from five separate experiments in
which hippocampal slices (from the same animal) either were untreated
(open bar) or were exposed to a 10 min bath application
of 200 nM ISO alone, 200 nM carbachol
(CCh) alone, or ISO plus carbachol (filled
bars). Compared with basal levels of cAMP seen in untreated
control slices, only ISO alone and ISO plus carbachol induced
significant increases in cAMP levels (*p < 0.05).
In four of these experiments a pair of slices also was exposed to a 10 min bath application of 50 µM forskolin. In these slices
cAMP levels were increased to 92.5 ± 13.1 pmol/mg of
protein.
|
|
MEK inhibitors suppress 5 Hz stimulation-induced LTP
Numerous studies have demonstrated that a variety of
neurotransmitters can activate signaling cascades that lead to MAPK
activation in neurons (Bading and Greenberg, 1991; Kurino et al., 1995;
Baron et al., 1996; English and Sweatt, 1996; Fukunaga and Miyamoto, 1998; Otani et al., 1999; Roberson et al., 1999; Winder et al., 1999;
Rosenblum et al., 2000). Indeed, Roberson et al. (1999) recently have
shown that, in the hippocampus, both muscarinic and -adrenergic
receptors are linked to the MAPK signaling cascade (see also Winder et
al., 1999; Rosenblum et al., 2000). This, along with the results from
studies showing that MAPK activity is required for the induction of
NMDA receptor-dependent LTP by high-frequency stimulation (English and
Sweatt, 1997; Atkins et al., 1998; Coogan et al., 1999, Jones et al.,
1999; Rosenblum et al., 2000), led us to investigate whether MAPK
activation has an important role in either the induction of 5 Hz
stimulation-induced LTP or its modulation by concurrent -adrenergic
and cholinergic receptor activation. In these experiments we first
examined the effects of MEK inhibitors on the induction of LTP by a
longer-duration 5 Hz stimulation train (30 sec) that induces robust
levels of LTP even in the absence of ISO and carbachol (Thomas et al.,
1996, 1998). Although 30 sec of 5 Hz stimulation induced significant LTP in vehicle control-treated slices (0.33% DMSO), it had little effect on synaptic strength in slices incubated in aCSF containing the
MEK inhibitor PD98059 (50 µM) for 60 min before the 5 Hz
stimulation (Fig. 3B).
Although this suggests that MAPK activation is required for the
induction of LTP by 5 Hz stimulation, PD98059 not only prevents
high-frequency stimulation-induced activation of MAPK but also can
inhibit activation of the
Ca2+/calmodulin-dependent kinase CaMKII in
hippocampal slices (Liu et al., 1999). Thus, some of the effects of
PD98059 on the induction of LTP might be attributable to indirect
effects on CaMKII activation. We therefore also examined the effects of
two additional MEK inhibitors, U0126 (Favata et al., 1998) and SL327,
which have been shown to block MAPK activation potently at
concentrations that have little effect on PKA, protein kinase C (PKC),
and CaMKII activity (Atkins et al., 1998; Roberson et al., 1999). As
shown in Figure 3, A and B, both U0126 (20 µM) and SL327 (10 µM)
inhibited the induction of LTP by a 30-sec-long train of 5 Hz
stimulation. Consistent with the recent report by Winder et al. (1999),
we found that the same concentration of U0126 that inhibited 5 Hz
stimulation-induced LTP had no significant effect on the amount of LTP
present 60 min after high-frequency stimulation (Fig. 3C),
suggesting that MAPK activation may be particularly important for the
induction of LTP by low-frequency synaptic stimulation.
View larger version (30K):
[in this window]
[in a new window]
|
Figure 3.
MEK inhibitors suppress low-frequency, but not
high-frequency, stimulation-induced LTP. A, The amount
of LTP induced by 30 sec of 5 Hz stimulation (delivered at time
0) in slices continuously bathed in 20 µM
U0126 (filled symbols; fEPSPs were
122.2 ± 5.1% of baseline; n = 6) was reduced
significantly (p < 0.01) as compared with
that seen in interleaved vehicle control experiments (open
symbols; 0.2% DMSO; fEPSPs were potentiated to 167.7 ± 9.9% of baseline; n = 5). B,
Summary of the effects of three different MEK inhibitors on 5 Hz
stimulation-induced LTP. Values show the amount of LTP present 40-45
min after 5 Hz stimulation. Similar amounts of LTP were induced by 5 Hz
stimulation in interleaved vehicle control experiments (0.1-0.33%
DMSO; n = 17), and the combined results are shown
by the open bar. Results for U0126 are from the same
experiments shown in A. fEPSPs in PD98059
(PD)-treated slices were 109.9 ± 9% of baseline
(n = 5) after 5 Hz stimulation
(**p < 0.01 compared with 0.33% DMSO control
experiments), whereas fEPSPs were 118.4 ± 13.4% of baseline
(n = 7) after 5 Hz stimulation in SL327
(SL)-treated slices (*p < 0.05 compared with 0.1% DMSO control experiments). In interleaved control
experiments the fEPSPs were 155.1 ± 5.9% of baseline (0.33%
DMSO; n = 5) and 165.1 ± 17.4% of baseline
(0.1% DMSO; n = 7), respectively.
C, High-frequency stimulation-induced LTP is not
inhibited by U0126. Two 1-sec-long trains of 100 Hz stimulation
(intertrain interval, 10 sec; delivered at time 0)
induced similar amounts of LTP in vehicle control experiments (0.2%
DMSO; open symbols; n = 6) and in
slices continuously bathed in 20 µM U0126
(filled symbols; n = 5). In
control experiments 55-60 min after 100 Hz stimulation the fEPSPs were
potentiated to 185.9 ± 20.5% of baseline, whereas in
U0126-treated slices the fEPSPs were 188.7 ± 43.2% of baseline.
D, Summary of the effects of MEK inhibitors on 5 Hz
stimulation-induced complex spike bursting. The plot shows the
percentage of EPSPs during the 5 Hz stimulation train that evoked
complex spike bursts (CSB, defined as two or more
negative-going spikes after EPSP onset; see Thomas et al., 1998) in
vehicle control experiments (left) and in the presence
of MEK inhibitors (right). Measurements were taken from
the experiments shown in B. Although complex spike
bursting tended to be reduced in slices pretreated with MEK inhibitors,
none of the inhibitors produced a statistically significant suppression
of complex spike bursting when compared with interleaved vehicle
control experiments (PD98059 vs 0.33% DMSO controls:
t(8) = 1.78, p = 0.11; U0126 vs 0.2% DMSO controls:
t(9) = 1.16, p = 0.28; SL327 vs 0.1% DMSO controls:
t(11) = 1.12, p = 0.29).
|
|
How might MAPK activation be involved in the induction of LTP by
low-frequency stimulation? Unlike high-frequency stimulation, the
induction of LTP by 5 Hz trains of synaptic stimulation in the
hippocampal CA1 region requires EPSP-evoked, complex spike-like bursts
of postsynaptic action potentials (Thomas et al., 1998). Recently,
Winder and colleagues (1999) found that both PD98059 and U0126 suppress
complex spike bursting during 5 Hz stimulation, suggesting that MEK
inhibitors may inhibit 5 Hz stimulation-induced LTP by suppressing the
EPSP-evoked complex spike bursting required for LTP induction by this
protocol. Although we did observe a tendency for EPSP-evoked complex
spike bursting to be reduced in PD98059- and SL327-treated slices, none
of the MEK inhibitors used in our experiments produced a statistically
significant inhibition of EPSP-evoked complex spike bursting during 5 Hz stimulation (Fig. 3D). Although this suggests that a
suppression of complex spike bursting is unlikely to account for the
effects of MEK inhibitors on 5 Hz stimulation-induced LTP,
extracellular recordings of complex spike bursting may lack the
resolution needed to detect modest changes in excitability that still
could influence LTP induction substantially. Moreover, effects of MEK
inhibitors on excitability that are near threshold for detection in
extracellular recordings also might be more or less obvious depending
on experimental conditions and thus also could account for the
different effects of MEK inhibitors on complex spike bursting observed
in our experiments and those of Winder et al. (1999). We thus examined
whether blocking MAPK activation inhibits LTP under conditions in which
changes in postsynaptic excitability should have little effect on LTP
induction. In these experiments we used whole-cell current-clamp
techniques to record EPSPs from individual CA1 pyramidal cells and
applied SL327 either in the bath or selectively to the postsynaptic CA1
pyramidal cells via the recording electrode. To minimize potential
effects of SL327 on LTP induction that might arise from changes in
postsynaptic excitability, we used a cesium-based intracellular
solution containing TEA to block potassium conductances and induced LTP
by pairing low-frequency presynaptic stimulation with depolarization of
the postsynaptic cell to near 0 mV (see Materials and Methods).
Although bath-applied SL327 inhibited the induction of LTP by 5 Hz
stimulation, neither bath application nor postsynaptic injection of
SL327 inhibited pairing-induced LTP (Fig.
4). Because SL327 does not inhibit the induction of LTP by a low-frequency stimulation protocol under conditions designed to minimize potential effects on LTP induction attributable to changes in neuronal excitability, our results suggest
that MEK inhibitors may suppress the induction of LTP by low-frequency
stimulation-induced complex spike bursting via effects on membrane
excitability that reduce NMDA receptor activation.
View larger version (21K):
[in this window]
[in a new window]
|
Figure 4.
SL327 does not inhibit the induction of LTP by
low-frequency synaptic stimulation paired with postsynaptic
depolarization. A, One hundred EPSPs (evoked at 2 Hz)
were paired with tonic postsynaptic depolarization to between 0 and +20
mV at time 0 in vehicle control experiments (open
circles; 0.2% DMSO in electrode-filling solution;
n = 12) and in experiments in which SL327 was
present either in the bath (filled circles; 10 µM, 0.1% DMSO; n = 7) or in the
recording electrode-filling solution (filled
triangles; 100 µM, 0.2% DMSO;
n = 12). The 25-30 min postpairing EPSPs were
potentiated to 241.5 ± 26.9% of baseline in control experiments,
255.5 ± 28.7% of baseline in experiments in which SL327 was
bath-applied, and 234.1 ± 27.5% of baseline in experiments in
which SL327 was injected into CA1 pyramidal cells via the recording
electrode. The inset shows EPSPs (average of three
responses) recorded during baseline and 30 min postpairing (larger
response) in a control experiment (left
traces) and in an experiment in which 100 µM SL327 was present in the recording electrode
(right traces). Calibration: 5 mV, 15 msec. B, Cumulative probability distribution showing
results from all of the experiments depicted in A.
Results from experiments in which SL327 was bath-applied
(filled circles) and applied via the recording
electrode (filled triangles) have been combined
into one distribution.
|
|
Coactivation of -adrenergic and cholinergic receptors
synergistically activates p42 MAPK
Because our experiments with MEK inhibitors suggested that MAPK
activation has a role in the induction of LTP by low-frequency stimulation protocols, we investigated whether concurrent activation of
-adrenergic and cholinergic receptors enhances the induction of LTP
by a brief train of 5 Hz stimulation by activating MAPK. First, this
hypothesis predicts that the potentiation induced by 5 sec of 5 Hz
stimulation in the presence of ISO and carbachol should be suppressed
by inhibitors of MAPK activation. Consistent with this, U0126 had
little effect on the change in synaptic strength induced by 5 Hz
stimulation alone (fEPSPs were 116.0 ± 8.8% of baseline 45 min
after 5 Hz stimulation alone in U0126-treated slices; n = 6) but significantly inhibited the induction of LTP by 5 Hz
stimulation in the presence of ISO and carbachol (Fig. 5A). The MEK inhibitor PD98059
(50 µM) also significantly
(p < 0.05) suppressed the induction of LTP by 5 Hz stimulation in ISO plus carbachol (fEPSPs were potentiated to
110.9 ± 7.2% of baseline, n = 4, compared with
163.9 ± 9.9% of baseline in DMSO control experiments,
n = 5). Second, this hypothesis indicates that ISO and
carbachol should have at least additive effects on MAPK activation in
hippocampal slices. To examine this possibility, we used Western blotting analysis with antibodies that specifically recognize dually
phosphorylated p42/p44 MAPK to examine levels of MAPK activation in
hippocampal slices exposed to a 10 min bath application of either ISO
alone, carbachol alone, or ISO plus carbachol. At the low
concentrations of ISO and carbachol used in our experiments, neither
ISO nor carbachol alone produced a significant increase in phospho-MAPK
levels in seven separate experiments (Fig. 5B1,B2). In
contrast, levels of dually phosphorylated p42-MAPK were increased >10-fold, whereas total MAPK levels were not changed significantly, in
slices in which ISO and carbachol were coapplied (Fig.
5B1,B2).
View larger version (26K):
[in this window]
[in a new window]
|
Figure 5.
MAPK activation may underlie the effects of ISO
plus carbachol on 5 Hz stimulation-induced LTP. A, U0126
inhibits the induction of LTP by 5 sec of 5 Hz stimulation delivered
during the coapplication of ISO and carbachol. A 5 sec train of 5 Hz
stimulation delivered at the end of a 10 min bath application of ISO
plus carbachol (200 nM each; the presence of agonists in
the bath indicated by the bar) induced robust LTP in
vehicle (0.2% DMSO) control experiments (open symbols;
fEPSPs were potentiated to 163.9 ± 6.8% of baseline;
n = 5) but had little effect on synaptic strength
in slices continuously bathed in 20 µM U0126
(filled symbols; fEPSPs were 112.8 ± 7.3%
of baseline; n = 5). The traces show
superimposed fEPSPs recorded during baseline and 45 min post-5 Hz
stimulation in a control experiment (left) and in a
slice bathed in U0126 (right). Calibration: 1 mV, 5 msec. B, Synergistic activation of MAPK by coactivation
of -adrenergic and cholinergic receptor agonists. B1,
Representative Western immunoblots showing protein bands visualized
with antibodies to dually phosphorylated p42/44 MAPK
(PP) and total p42/44 MAPK (Total)
in control, untreated slices (Con), and slices bathed
for 10 min in aCSF containing 200 nM ISO, 200 nM carbachol (CCh), or ISO plus carbachol
(ISO + CCh). B2, Average results ± SEM from seven separate experiments like that shown in
B1. Only coapplication of ISO plus carbachol induced a
statistically significant (*p < 0.05) increase in
phospho-p42 MAPK levels.
|
|
| |
DISCUSSION |
Coactivation of -adrenergic and cholinergic receptors has
synergistic effects on both LTP induction and MAPK activation in the
CA1 region of the hippocampus
Behavioral studies indicate that interactions between
noradrenergic and cholinergic receptor signaling have an important role in learning and memory (Decker and Gallagher, 1987; McGaugh, 1989; Decker et al., 1990; Harrell et al., 1990; Riekkinen et al., 1990; Decker and McGaugh, 1991; Ohno et al., 1993, 1997). Although the behavioral expression of these interactions potentially could arise
from effects of norepinephrine and acetylcholine at multiple levels of
CNS function, one possibility is that these transmitters interact at
the cellular level to regulate activity-dependent changes in synaptic
strength involved in the storage of new information during learning. We
thus examined whether coactivation of cholinergic and -adrenergic
receptors modulates LTP induction in the hippocampal CA1 region. Our
results show that, whereas low concentrations of carbachol and ISO by
themselves have little effect on LTP, coapplication of carbachol and
ISO dramatically facilitates the induction of LTP by low-frequency
trains of synaptic stimulation. This effect does not appear to arise
from synergistic or additive effects on adenylyl cyclase activity,
because cAMP levels in slices exposed to both ISO and carbachol were
not different from those seen in slices exposed to ISO alone. Instead,
coapplication of ISO and carbachol synergistically activated p42 MAPK,
suggesting that the MAPK signaling pathway may have an important role
in the modulation of 5 Hz stimulation-induced LTP by concurrent
-adrenergic and cholinergic receptor activation.
MAPK signaling is required for the induction of LTP by 5 Hz trains
of synaptic stimulation
Emerging evidence indicates that the MAPK signaling cascade has an
important role in learning (Atkins et al., 1998; Berman et al., 1998;
Crow et al., 1998; Blum et al., 1999) and in forms of synaptic
plasticity, such as LTP, that are thought to be involved in learning
(English and Sweatt, 1997; Rosenblum et al., 2000) (see also Martin et
al., 1997; Atkins et al., 1998; Coogan et al., 1999; Winder
et al., 1999). Although many of the molecular details of the role of
MAPK in synaptic plasticity are unknown, it seems likely that MAPK is
involved in multiple aspects of synaptic plasticity. First,
MAPK appears to contribute to the CREB-dependent activation of gene
expression required for the long-lasting, protein synthesis-dependent
stages of long-term memory and synaptic potentiation in both the
hippocampus (Impey et al., 1998) and in Aplysia (Martin et
al., 1997). Second, recent findings suggest that MAPK also acts on
cytoplasmic targets required for the induction and/or early stages of
LTP maintenance (English and Sweatt, 1997; Atkins et al., 1998; Coogan
et al., 1999; Jones et al., 1999; Winder et al., 1999; Rosenblum et
al., 2000). Consistent with this, we found that three different
inhibitors of MAPK activation strongly suppressed LTP induced by 5 Hz
trains of synaptic stimulation. Although our results do not rule out a
role for MAPK in the maintenance phase of LTP, the effects of MEK
inhibitors on 5 Hz stimulation-induced LTP were evident almost
immediately after 5 Hz stimulation, suggesting that inhibiting MAPK
activation interferes with LTP induction (see also English and Sweatt,
1997).
Although all three MEK inhibitors used in our experiments strongly
suppressed the induction of LTP by 5 Hz stimulation, U0126 and SL327
had no effect on high-frequency stimulation-induced and pairing-induced
LTP, respectively. Unlike high-frequency stimulation-induced LTP, the
induction of LTP by trains of 5 Hz stimulation requires EPSP-evoked
complex spike-like bursts of postsynaptic action potentials to provide
the depolarization needed for NMDA receptor activation (Thomas et al.,
1998). Thus, the selective effects of MEK inhibitors on 5 Hz
stimulation-induced LTP seen in our experiments might be attributable
to changes in postsynaptic excitability that inhibit complex spike
bursting during 5 Hz stimulation (see Winder et al., 1999). Although we
did not observe a strong suppression of complex spike bursting during 5 Hz stimulation in slices treated with MEK inhibitors, there was a
nonsignificant trend toward less bursting in the presence of MEK
inhibitors. Thus, to examine further whether changes in excitability
might contribute to the effects of MEK inhibitors on low-frequency
stimulation-induced LTP, we examined the effects of SL327 on the
induction of LTP by low-frequency presynaptic stimulation paired with
postsynaptic depolarization, a protocol in which changes in
postsynaptic excitability should have little effect on LTP induction.
Although blocking MAPK activation with SL327 strongly inhibited the
induction of LTP in experiments in which postsynaptic bursting during
low-frequency stimulation is required for the induction of LTP, it did
not inhibit the induction of LTP by low-frequency synaptic stimulation
paired with depolarizing current injections delivered through the
intracellular recording electrode. On the basis of these findings it
seems likely that MEK inhibitors suppress the induction of LTP by
low-frequency trains of synaptic stimulation via effects on
postsynaptic excitability. One possibility is that a NMDA
receptor-dependent activation of the MAPK signaling pathway during 5 Hz
stimulation enables LTP induction by a positive feedback mechanism that
amplifies NMDA receptor activation via a MAPK-dependent modulation of
ion channels that facilitates EPSP-induced postsynaptic depolarization.
Indeed, NMDA receptor activation leads to activation of the MAPK
signaling cascade in hippocampal neurons (Bading and Greenberg, 1991;
Kurino et al., 1995; English and Sweatt, 1996), and MAPK may
phosphorylate and inhibit the activity of some types of
K+ channels in hippocampal neurons (Adams
et al., 1997).
MAPK activation may underlie the effects of modulatory
neurotransmitters on LTP induction
Because MEK inhibitors suppress the induction of LTP by stronger
trains of 5 Hz stimulation that induce LTP in the absence of ISO and
carbachol, it is difficult to determine whether MAPK activation
mediates the modulatory effects of coactivation of -adrenergic and
cholinergic receptors on LTP induction by weaker 5 Hz stimulation
trains or whether inhibiting MAPK activation simply blocks the ability
of synapses to undergo LTP. MEK inhibitors do not, however, block the
induction of LTP by low-frequency synaptic stimulation paired
postsynaptic depolarization or by high-frequency stimulation,
suggesting that MAPK activation is not a necessary component of the
pathways responsible for LTP. Instead, our results suggest that MAPK
activation is part of a modulatory process important for LTP induction
by some patterns of synaptic stimulation. We thus favor the idea that
coactivation of -adrenergic and cholinergic receptors enhances the
induction of LTP via convergent effects on MAPK activation.
Importantly, synergistic activation of MAPK also appears to have a role
in the induction of long-term depression after coactivation of
G-protein-linked receptors for dopamine and glutamate at excitatory
synapses in prefrontal cortex (Otani et al., 1999). Thus, the MAPK
signaling cascade may represent a common mechanism by which a variety
of neurotransmitters may act to regulate activity-dependent changes in
synaptic strength.
In the hippocampus the activation of MAPK after -adrenergic receptor
activation is blocked by PKA inhibitors, whereas MAPK activation
induced by carbachol is prevented by inhibitors of PKC (Roberson et
al., 1999). Because direct activation of adenylyl cyclase with
forskolin and of PKC with phorbol esters synergistically activates
MAPKs in some cells (Frodin et al., 1994; Yamazaki et al., 1997), the
synergistic effects of -adrenergic and cholinergic receptor agonists
on MAPK activation in the hippocampus observed in our experiments most
likely arise from interactions occurring downstream of adenylyl cyclase
and PKC activation. One possibility is that this occurs at the level of
MEK activation via the combined effects of a PKC-mediated activation of
Raf-1 (Kolch et al., 1993; Marais et al., 1998) and a cAMP-dependent
activation of B-Raf (Vossler et al., 1997; de Rooij et al., 1998;
Kawasaki et al., 1998). Recent evidence suggests, however, that B-Raf
and Raf-1 are localized to different cellular compartments (dendritic
vs somatic, respectively) in CA1 pyramidal cells (Morice et al., 1999).
Moreover, muscarinic receptor activation also can activate the MAPK
signaling pathway in neurons via a PKC-independent mechanism involving
Src family kinases and phosphoinositide-3 kinase (Rosenblum et al.,
2000). Finally, some of the effects of -adrenergic receptor activation on LTP induction appear to be attributable to a
PKA-dependent suppression of protein phosphatase activity (Thomas et
al., 1996), and protein phosphatase inhibition can lead to MAPK
activation in hippocampal neurons (Runden et al., 1998). Thus,
interactions at several points in the MAPK signaling cascade
potentially might contribute to the synergistic effects of ISO and
carbachol on MAPK activation in the CA1 region of the hippocampus. Our
results suggest, however, that understanding the actions and
interactions of G-protein-coupled receptors on MAPK signaling may
provide important insights into how modulatory neurotransmitters
regulate activity-dependent changes in synaptic strength that
contribute to memory formation during learning.
| |
FOOTNOTES |
Received March 14, 2000; revised May 18, 2000; accepted May 25, 2000.
This work was supported by grants from the National Institute of Mental
Health, the Pew Charitable Trusts, the UCLA Center on Aging, and Dr. P. Gail Mahoney to T.J.O. P.A.Z. was supported by a Howard Hughes
Medical Institute Predoctoral Fellowship. T.J.O. is a member of the
UCLA Brain Research Institute. We are grateful to Mark Barad, Holly
Carlisle, and Kelsey Martin for comments on an earlier version of this
manuscript and to Chris Evans and Joseph Watson for use of equipment
and reagents for biochemical assays. We thank James Trzaskos, Janice
Hytrek, James Piecara, Christine Tabaka, and Jia-Sheng Yan of DuPont
Pharmaceuticals for a generous gift of SL327.
Correspondence should be addressed to Dr. Thomas O'Dell, Department of
Physiology, University of California Los Angeles School of Medicine,
53-231 Center for the Health Sciences, 10833 Le Conte Avenue, Los
Angeles, CA 90095. E-mail: todell{at}mednet.ucla.edu.
| |
REFERENCES |
-
Adams JP,
Anderson AE,
Johnston D,
Pfaffinger PJ,
Sweatt JD
(1997)
Kv4.2: a novel substrate for MAP kinase phosphorylation.
Soc Neurosci Abstr
23:1176.
-
Atkins CM,
Selcher JC,
Petraitis JJ,
Trzaskos JM,
Sweatt JD
(1998)
The MAPK cascade is required for mammalian associative learning.
Nat Neurosci
1:602-609[Web of Science][Medline].
-
Bading H,
Greenberg ME
(1991)
Stimulation of protein tyrosine phosphorylation by NMDA receptor activation.
Science
253:912-914[Abstract/Free Full Text].
-
Baron C,
Benes C,
Tan HV,
Fagard R,
Roisin M-P
(1996)
Potassium chloride pulse enhances mitogen-activated protein kinase activity in rat hippocampal slices.
J Neurochem
66:1005-1010[Web of Science][Medline].
-
Baumgold J
(1992)
Muscarinic receptor-mediated stimulation of adenylyl cyclase.
Trends Pharmacol Sci
13:339-340[Medline].
-
Berman DE,
Hazvi S,
Rosenblum K,
Seger R,
Yadin D
(1998)
Specific and differential activation of mitogen-activated protein kinase cascades by unfamiliar taste in the insular cortex of the behaving rat.
J Neurosci
18:10037-10044[Abstract/Free Full Text].
-
Bliss TVP,
Collingridge GL
(1993)
A synaptic model of memory: long-term potentiation in the hippocampus.
Nature
361:31-39[Medline].
-
Blitzer RD,
Gil O,
Landau EM
(1990)
Cholinergic stimulation enhances long-term potentiation in the CA1 region of rat hippocampus.
Neurosci Lett
118:207-210.
-
Blitzer RD,
Wong T,
Nouranifar R,
Iyengar R,
Landau EM
(1995)
Postsynaptic cAMP pathway gates early LTP in the hippocampal CA1 region.
Neuron
15:1403-1414[Web of Science][Medline].
-
Blitzer RD,
Connor JH,
Brown GP,
Wong T,
Shenolikar S,
Iyengar R,
Landau EM
(1998)
Gating of CaMKII by cAMP-regulated protein phosphatase activity during LTP.
Science
280:1940-1943[Abstract/Free Full Text].
-
Blokland A
(1996)
Acetylcholine: a neurotransmitter for learning and memory?
Brain Res Rev
21:285-300.
-
Blum S,
Moore AN,
Adams F,
Dash PK
(1999)
A mitogen-activated protein kinase cascade in the CA1/CA2 subfield of the dorsal hippocampus is essential for long-term spatial memory.
J Neurosci
19:3535-3544[Abstract/Free Full Text].
-
Bradford M
(1976)
A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding.
Anal Biochem
72:248-252[Web of Science][Medline].
-
Brocher S,
Artola A,
Singer W
(1992)
Agonists of cholinergic and noradrenergic receptors facilitate synergistically the induction of long-term potentiation in slices of rat visual cortex.
Brain Res
573:27-36[Web of Science][Medline].
-
Coogan AN,
O'Leary DM,
O'Connor JJ
(1999)
p42/44 MAP kinase inhibitor PD98059 attenuates multiple forms of synaptic plasticity in rat dentate gyrus in vitro.
J Neurophysiol
81:103-110[Abstract/Free Full Text].
-
Cooper DMF,
Mons N,
Karpen JW
(1995)
Adenylyl cyclases and the interaction between calcium and cAMP signaling.
Nature
374:421-424[Medline].
-
Crow T,
Xue-Bian J-J,
Siddiqi V,
Kang Y,
Neary JT
(1998)
Phosphorylation of mitogen-activated protein kinase by one-trial and multi-trial classical conditioning.
J Neurosci
18:3480-3487[Abstract/Free Full Text].
-
Decker MW,
Gallagher M
(1987)
Scoploamine-disruption of radial arm maze performance: modification by noradrenergic depletion.
Brain Res
417:59-69[Web of Science][Medline].
-
Decker MW,
McGaugh JL
(1991)
The role of interactions between the cholinergic system and other neuromodulatory systems in learning and memory.
Synapse
7:151-168[Web of Science][Medline].
-
Decker MW,
Gill TM,
McGaugh JL
(1990)
Concurrent muscarinic and -adrenergic blockade in rats impairs place-learning in a water maze and retention of inhibitory avoidance.
Brain Res
513:81-85[Web of Science][Medline].
-
de Rooij J,
Zwartkruis FJT,
Verheijen MHG,
Cool RH,
Nijman SM,
Wittinghofer A,
Bos JL
(1998)
Epac is a Rap1 guanine-nucleotide-exchange factor directly activated by cyclic AMP.
Nature
396:474-477[Medline].
-
English JD,
Sweatt JD
(1996)
Activation of p42 mitogen-activated protein kinase in hippocampal long-term potentiation.
J Biol Chem
271:24329-24332[Abstract/Free Full Text].
-
English JD,
Sweatt JD
(1997)
A requirement for the mitogen-activated protein kinase cascade in hippocampal long-term potentiation.
J Biol Chem
272:19103-19106[Abstract/Free Full Text].
-
Favata M,
Horiuchi KY,
Manos EJ,
Daulerio AJ,
Stradley DA,
Feeser WS,
Van Dyk DE,
Pitts WJ,
Earl RA,
Hobbs F,
Copeland RA,
Magolda RL,
Scherle PA,
Trzaskos JM
(1998)
Identification of a novel inhibitor of mitogen-activated protein kinase kinase.
J Biol Chem
273:18623-18632[Abstract/Free Full Text].
-
Frodin M,
Peraldi P,
Van Obberghen E
(1994)
Cyclic AMP activates the mitogen-activated protein kinase cascade in PC12 cells.
J Biol Chem
269:6207-6214[Abstract/Free Full Text].
-
Fukunaga K,
Miyamoto E
(1998)
Role of MAP kinase in neurons.
Mol Neurobiol
16:79-95[Web of Science][Medline].
-
Harrell LE,
Peagler A,
Parson DS
(1990)
Adrenoreceptor antagonist treatment influences recovery of learning following medial septal lesions and hippocampal sympathetic ingrowth.
Pharmacol Biochem Behav
35:21-28[Medline].
-
Huerta PT,
Lisman JE
(1993)
Heightened synaptic plasticity of hippocampal CA1 neurons during a cholinergically induced rhythmic state.
Nature
364:723-725[Medline].
-
Impey S,
Obrietan K,
Wong ST,
Poser S,
Yano S,
Wayman G,
Deloulme JC,
Chan G,
Storm DR
(1998)
Cross talk between ERK and PKA is required for Ca2+ stimulation of CREB-dependent transcription and ERK nuclear translocation.
Neuron
21:869-883[Web of Science][Medline].
-
Izquierdo I,
Medina JH
(1995)
Correlation between the pharmacology of long-term potentiation and the pharmacology of memory.
Neurobiol Learn Mem
53:19-32.
-
Izumi Y,
Zorumski CF
(1999)
Norepinephrine promotes long-term potentiation in the adult rat hippocampus in vitro.
Synapse
31:196-202[Web of Science][Medline].
-
Jerusalinsky D,
Kornisiuk E,
Izquierdo I
(1997)
Cholinergic neurotransmission and synaptic plasticity concerning memory processing.
Neurochem Res
22:507-515[Medline].
-
Jones MW,
French PJ,
Bliss TVP,
Rosenblum K
(1999)
Molecular mechanisms of long-term potentiation in the insular cortex in vivo.
J Neurosci
19:RC361-RC368.
-
Katsuki H,
Izumi Y,
Zorumski CF
(1997)
Noradrenergic regulation of synaptic plasticity in the hippocampal CA1 region.
J Neurophysiol
77:3013-3020[Abstract/Free Full Text].
-
Kawasaki H,
Springett GM,
Mochizuki N,
Toki S,
Nakaya M,
Matsuda M,
Housman DE,
Graybiel AM
(1998)
A family of cAMP-binding proteins that directly activate rap1.
Science
282:2275-2279[Abstract/Free Full Text].
-
Kolch W,
Heldecker G,
Kochs G,
Hummel R,
Vahldl H,
Mischak H,
Finkenzeller G,
Marme D,
Rapp UR
(1993)
Protein kinase C- activates raf-1 by direct phosphorylation.
Nature
364:249-252[Medline].
-
Kurino M,
Fukunaga K,
Ushio Y,
Miyamoto E
(1995)
Activation of mitogen-activated protein kinase in cultured rat hippocampal neurons by stimulation of glutamate receptors.
J Neurochem
65:1282-1289[Web of Science][Medline].
-
Liu J,
Fukunaga K,
Yamamoto H,
Nishi K,
Miyamoto E
(1999)
Differential roles of Ca2+/calmodulin-dependent protein kinase II and mitogen-activated protein kinase activation in hippocampal long-term potentiation.
J Neurosci
19:8292-8299[Abstract/Free Full Text].
-
Marais R,
Light Y,
Mason C,
Paterson H,
Olson MF,
Marshall CJ
(1998)
Requirement of Ras-GTP-Raf complexes for activation of Raf-1 by protein kinase C.
Science
280:109-112[Abstract/Free Full Text].
-
Martin KC,
Michael D,
Rose JC,
Barad M,
Casadio A,
Zhu H,
Kandel ER
(1997)
MAP kinase translocates into the nucleus of the presynaptic cell and is required for long-term facilitation in Aplysia.
Neuron
18:899-912[Web of Science][Medline].
-
McGaugh JL
(1989)
Involvement of hormonal and neuromodulatory systems in the regulation of memory storage.
Annu Rev Neurosci
12:255-287[Web of Science][Medline].
-
Mons N,
Cooper DMF
(1995)
Adenylate cyclases: critical foci in neuronal signaling.
Trends Neurosci
18:536-542[Web of Science][Medline].
-
Morice C,
Nothias F,
Konig S,
Vernier P,
Baccarini M,
Vincent J-D,
Barnier JV
(1999)
Raf-1 and B-Raf proteins have similar regional distributions but differential subcellular localization in adult rat brain.
Eur J Neurosci
11:1995-2006[Web of Science][Medline].
-
Ohno M,
Yamamoto T,
Kobayashi M,
Watanabe S
(1993)
Impairment of working memory induced by scopolamine in rats with noradrenergic DSP-4 lesions.
Eur J Pharmacol
238:117-120[Medline].
-
Ohno M,
Yoshimatsu A,
Kobayashi M,
Watanabe S
(1997)
Noradrenergic DSP-4 lesions aggravate impairment of working memory produced by hippocampal muscarinic blockade in rats.
Pharmacol Biochem Behav
57:257-261[Medline].
-
Otani S,
Auclair N,
Desce J-M,
Roisin M-P,
Crepel F
(1999)
Dopamine receptors and Groups I and II mGluRs cooperate for long-term depression induction in rat prefrontal cortex through converging postsynaptic activation of MAP kinase.
J Neurosci
19:9788-9802[Abstract/Free Full Text].
-
Peterson GL
(1977)
A simplification of the protein assay method of Lowry et al. which is more generally applicable.
Anal Biochem
83:346-356[Web of Science][Medline].
-
Riekkinen P,
Sirvio J,
Valjakka A,
Pitkanen A,
Partanen J,
Riekkinen P
(1990)
The effects of concurrent manipulations of cholinergic and noradrenergic systems on neocortical EEG and spatial learning.
Behav Neural Biol
54:204-210[Medline].
-
Roberson ED,
English JD,
Adams JP,
Selcher JC,
Kondratick C,
Sweatt JD
(1999)
The mitogen-activated protein kinase cascade couples PKA and PKC to cAMP response element binding protein phosphorylation in area CA1 of hippocampus.
J Neurosci
19:4337-4348[Abstract/Free Full Text].
-
Rosenblum K,
Futter M,
Jones M,
Hulme EC,
Bliss TVP
(2000)
ERKI/II regulation by the muscarinic acetylcholine receptors in neurons.
J Neurosci
20:977-985[Abstract/Free Full Text].
-
Runden E,
Seglen PO,
Haug F-M,
Ottersen OP,
Wieloch T,
Shamloo M,
Laake JH
(1998)
Regional selective neuronal degeneration after protein phosphatase inhibition in hippocampal slice cultures: evidence for a MAP kinase-dependent mechanism.
J Neurosci
18:7296-7305[Abstract/Free Full Text].
-
Sah P,
Bekkers JM
(1996)
Apical dendritic location of slow afterhyperpolarization current in hippocampal neurons: implications for the integration of long-term potentiation.
J Neurosci
16:4537-4542[Abstract/Free Full Text].
-
Thomas MJ,
Moody T,
Makhinson M,
O'Dell TJ
(1996)
Activity-dependent -adrenergic modulation of low-frequency stimulation-induced LTP in the hippocampal CA1 region.
Neuron
17:475-482[Web of Science][Medline].
-
Thomas MJ,
Watabe AW,
Moody TD,
Makhinson M,
O'Dell TJ
(1998)
Postsynaptic complex spike bursting enables the induction of LTP by theta frequency synaptic stimulation.
J Neurosci
18:7118-7126[Abstract/Free Full Text].
-
Vossler MR,
Yao H,
York RD,
Pan M-G,
Rim CS,
Stork PJS
(1997)
cAMP activates MAP kinase and Elk-1 through a B-Raf- and Rap1-dependent pathway.
Cell
89:73-82[Web of Science][Medline].
-
Winder DG,
Martin KC,
Muzzio IA,
Rohrer D,
Chruscinski A,
Kobilka B,
Kandel ER
(1999)
ERK plays a regulatory role in induction of LTP by theta frequency stimulation and its modulation by -adrenergic receptors.
Neuron
24:715-726[Web of Science][Medline].
-
Yamazaki T,
Komuro I,
Zou Y,
Kudoh S,
Mizuno T,
Hiroi Y,
Shiojima I,
Takano H,
Kinugawa K-I,
Kohmoto O,
Takahashi T,
Yazaki Y
(1997)
Protein kinase A and protein kinase C synergistically activate the Raf-1 kinase/mitogen-activated protein kinase cascade in neonatal rat cardiomyocytes.
J Mol Cell Cardiol
29:2491-2501[Web of Science][Medline].
Copyright © 2000 Society for Neuroscience 0270-6474/00/20165924-08$05.00/0
This article has been cited by other articles:
|
|
|
|
 
A. E. Fink and T. J. O'Dell
Short Trains of Theta Frequency Stimulation Enhance CA1 Pyramidal Neuron Excitability in the Absence of Synaptic Potentiation
J. Neurosci.,
September 9, 2009;
29(36):
11203 - 11214.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. J. Butcher, I. Torrecilla, K. W. Young, K. C. Kong, S. C. Mistry, A. R. Bottrill, and A. B. Tobin
N-Methyl-D-aspartate Receptors Mediate the Phosphorylation and Desensitization of Muscarinic Receptors in Cerebellar Granule Neurons
J. Biol. Chem.,
June 19, 2009;
284(25):
17147 - 17156.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Fukushima, R. Maeda, R. Suzuki, A. Suzuki, M. Nomoto, H. Toyoda, L.-J. Wu, H. Xu, M.-G. Zhao, K. Ueda, et al.
Upregulation of Calcium/Calmodulin-Dependent Protein Kinase IV Improves Memory Formation and Rescues Memory Loss with Aging
J. Neurosci.,
October 1, 2008;
28(40):
9910 - 9919.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Kemp and D. Manahan-Vaughan
{beta}-Adrenoreceptors Comprise a Critical Element in Learning-Facilitated Long-Term Plasticity
Cereb Cortex,
June 1, 2008;
18(6):
1326 - 1334.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. L. Scheiderer, C. C. Smith, E. McCutchen, P. A. McCoy, E. E. Thacker, K. Kolasa, L. E. Dobrunz, and L. L. McMahon
Coactivation of M1 Muscarinic and {alpha}1 Adrenergic Receptors Stimulates Extracellular Signal-Regulated Protein Kinase and Induces Long-Term Depression at CA3-CA1 Synapses in Rat Hippocampus
J. Neurosci.,
May 14, 2008;
28(20):
5350 - 5358.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. J. Sjostrom, E. A. Rancz, A. Roth, and M. Hausser
Dendritic Excitability and Synaptic Plasticity
Physiol Rev,
April 1, 2008;
88(2):
769 - 840.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
W. Morishita and R. C. Malenka
Mechanisms Underlying Dedepression of Synaptic NMDA Receptors in the Hippocampus
J Neurophysiol,
January 1, 2008;
99(1):
254 - 263.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Satoh, S. Endo, T. Ikeda, K. Yamada, M. Ito, M. Kuroki, T. Hiramoto, O. Imamura, Y. Kobayashi, Y. Watanabe, et al.
Extracellular Signal-Regulated Kinase 2 (ERK2) Knockdown Mice Show Deficits in Long-Term Memory; ERK2 Has a Specific Function in Learning and Memory
J. Neurosci.,
October 3, 2007;
27(40):
10765 - 10776.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C.-H. Yang, C.-C. Huang, and K.-S. Hsu
Novelty exploration elicits a reversal of acute stress-induced modulation of hippocampal synaptic plasticity in the rat
J. Physiol.,
December 1, 2006;
577(2):
601 - 615.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Wu, M. J. Rowan, and R. Anwyl
Long-Term Potentiation Is Mediated by Multiple Kinase Cascades Involving CaMKII or Either PKA or p42/44 MAPK in the Adult Rat Dentate Gyrus In Vitro
J Neurophysiol,
June 1, 2006;
95(6):
3519 - 3527.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. Shirinyan, T. Teshiba, K. Taylor, P. O'Neill, S. C. Lee, and F. B. Krasne
Rostral Ganglia Are Required for Induction But Not Expression of Crayfish Escape Reflex Habituation: Role of Higher Centers in Reprogramming Low-Level Circuits
J Neurophysiol,
April 1, 2006;
95(4):
2721 - 2724.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. J. Pocklington, J. D. Armstrong, and S. G. N. Grant
Organization of brain complexity--synapse proteome form and function
Brief Funct Genomic Proteomic,
March 1, 2006;
5(1):
66 - 73.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. A. Schrader, S. G. Birnbaum, B. M. Nadin, Y. Ren, D. Bui, A. E. Anderson, and J. D. Sweatt
ERK/MAPK regulates the Kv4.2 potassium channel by direct phosphorylation of the pore-forming subunit
Am J Physiol Cell Physiol,
March 1, 2006;
290(3):
C852 - C861.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. W. Barnett, R. F. Watson, T. Vitalis, K. Porter, N. H. Komiyama, P. N. Stoney, T. H. Gillingwater, S. G. N. Grant, and P. C. Kind
Synaptic Ras GTPase Activating Protein Regulates Pattern Formation in the Trigeminal System of Mice
J. Neurosci.,
February 1, 2006;
26(5):
1355 - 1365.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L.-L. Yuan, X. Chen, K. Kunjilwar, P. Pfaffinger, and D. Johnston
Acceleration of K+ channel inactivation by MEK inhibitor U0126
Am J Physiol Cell Physiol,
January 1, 2006;
290(1):
C165 - C171.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Navakkode, S. Sajikumar, and J. U. Frey
Mitogen-Activated Protein Kinase-Mediated Reinforcement of Hippocampal Early Long-Term Depression by the Type IV-Specific Phosphodiesterase Inhibitor Rolipram and Its Effect on Synaptic Tagging
J. Neurosci.,
November 16, 2005;
25(46):
10664 - 10670.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. A. Phares and J. H. Byrne
Analysis of 5-HT-Induced Short-Term Facilitation at Aplysia Sensorimotor Synapse During Bursts: Increased Synaptic Gain That Does Not Require ERK Activation
J Neurophysiol,
July 1, 2005;
94(1):
871 - 877.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. J. Voulalas, L. Holtzclaw, J. Wolstenholme, J. T. Russell, and S. E. Hyman
Metabotropic Glutamate Receptors and Dopamine Receptors Cooperate to Enhance Extracellular Signal-Regulated Kinase Phosphorylation in Striatal Neurons
J. Neurosci.,
April 13, 2005;
25(15):
3763 - 3773.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Z.-Y. Zhuang, H. Xu, D. E. Clapham, and R.-R. Ji
Phosphatidylinositol 3-Kinase Activates ERK in Primary Sensory Neurons and Mediates Inflammatory Heat Hyperalgesia through TRPV1 Sensitization
J. Neurosci.,
September 22, 2004;
24(38):
8300 - 8309.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. G. Birnbaum, A. W. Varga, L.-L. Yuan, A. E. Anderson, J. D. Sweatt, and L. A. Schrader
Structure and Function of Kv4-Family Transient Potassium Channels
Physiol Rev,
July 1, 2004;
84(3):
803 - 833.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Q. Wang, D. M. Walsh, M. J. Rowan, D. J. Selkoe, and R. Anwyl
Block of Long-Term Potentiation by Naturally Secreted and Synthetic Amyloid {beta}-Peptide in Hippocampal Slices Is Mediated via Activation of the Kinases c-Jun N-Terminal Kinase, Cyclin-Dependent Kinase 5, and p38 Mitogen-Activated Protein Kinase as well as Metabotropic Glutamate Receptor Type 5
J. Neurosci.,
March 31, 2004;
24(13):
3370 - 3378.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Straube, V. Korz, D. Balschun, and J. Uta Frey
Requirement of {beta}-adrenergic receptor activation and protein synthesis for LTP-reinforcement by novelty in rat dentate gyrus
J. Physiol.,
November 1, 2003;
552(3):
953 - 960.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. S. Leung, B. Shen, N. Rajakumar, and J. Ma
Cholinergic Activity Enhances Hippocampal Long-Term Potentiation in CA1 during Walking in Rats
J. Neurosci.,
October 15, 2003;
23(28):
9297 - 9304.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. C. Yang, Y. L. Ma, S. K. Chen, C. W. Wang, and E. H. Y. Lee
Focal Adhesion Kinase Is Required, But Not Sufficient, for the Induction of Long-Term Potentiation in Dentate Gyrus Neurons In Vivo
J. Neurosci.,
May 15, 2003;
23(10):
4072 - 4080.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y.-W. Lin, M.-Y. Min, T.-H. Chiu, and H.-W. Yang
Enhancement of Associative Long-Term Potentiation by Activation of {beta}-Adrenergic Receptors at CA1 Synapses in Rat Hippocampal Slices
J. Neurosci.,
May 15, 2003;
23(10):
4173 - 4181.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. Opazo, A. M. Watabe, S. G. N. Grant, and T. J. O'Dell
Phosphatidylinositol 3-Kinase Regulates the Induction of Long-Term Potentiation through Extracellular Signal-Related Kinase-Independent Mechanisms
J. Neurosci.,
May 1, 2003;
23(9):
3679 - 3688.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. E. Schulz, A. D. McIntosh, M. R. Kasten, B. Wieringa, and H. F. Epstein
A Role for Myotonic Dystrophy Protein Kinase in Synaptic Plasticity
J Neurophysiol,
March 1, 2003;
89(3):
1177 - 1186.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. R. Zarrindast, M. Ghiasvand, H. Homayoun, P. Rostami, B. Shafaghi, and S. Khavandgar
Adrenoceptor mechanisms underlying imipramine-induced memory deficits in rats
J Psychopharmacol,
January 1, 2003;
17(1):
83 - 88.
[Abstract]
[PDF]
|
|
|
|
|
|
|
G. L. Kovacs and E. Toldy
BASAL AND ISOPROTERENOL-STIMULATED CYCLIC-ADENOSINE MONOPHOSPHATE LEVELS IN MOUSE HIPPOCAMPUS AND LYMPHOCYTES DURING ALCOHOL TOLERANCE AND WITHDRAWAL
Alcohol Alcohol.,
January 1, 2003;
38(1):
11 - 17.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. C. Selcher, E. J. Weeber, J. Christian, T. Nekrasova, G. E. Landreth, and J. D. Sweatt
A Role for ERK MAP Kinase in Physiologic Temporal Integration in Hippocampal Area CA1
Learn. Mem.,
January 1, 2003;
10(1):
26 - 39.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. L. Berkeley and A. I. Levey
Cell-Specific Extracellular Signal-Regulated Kinase Activation by Multiple G Protein-Coupled Receptor Families in Hippocampus
Mol. Pharmacol.,
January 1, 2003;
63(1):
128 - 135.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
N. H. Komiyama, A. M. Watabe, H. J. Carlisle, K. Porter, P. Charlesworth, J. Monti, D. J. C. Strathdee, C. M. O'Carroll, S. J. Martin, R. G. M. Morris, et al.
SynGAP Regulates ERK/MAPK Signaling, Synaptic Plasticity, and Learning in the Complex with Postsynaptic Density 95 and NMDA Receptor
J. Neurosci.,
November 15, 2002;
22(22):
9721 - 9732.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L.-L. Yuan, J. P. Adams, M. Swank, J. D. Sweatt, and D. Johnston
Protein Kinase Modulation of Dendritic K+ Channels in Hippocampus Involves a Mitogen-Activated Protein Kinase Pathway
J. Neurosci.,
June 15, 2002;
22(12):
4860 - 4868.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Watanabe, D. A. Hoffman, M. Migliore, and D. Johnston
Dendritic K+ channels contribute to spike-timing dependent long-term potentiation in hippocampal pyramidal neurons
PNAS,
June 11, 2002;
99(12):
8366 - 8371.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. M. Vanhoose, M. Emery, L. Jimenez, and D. G. Winder
ERK Activation by G-protein-coupled Receptors in Mouse Brain Is Receptor Identity-specific
J. Biol. Chem.,
March 8, 2002;
277(11):
9049 - 9053.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. T. Dineley, M. Westerman, D. Bui, K. Bell, K. H. Ashe, and J. D. Sweatt
{beta}-Amyloid Activates the Mitogen-Activated Protein Kinase Cascade via Hippocampal {alpha}7 Nicotinic Acetylcholine Receptors: In Vitro and In Vivo Mechanisms Related to Alzheimer's Disease
J. Neurosci.,
June 15, 2001;
21(12):
4125 - 4133.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Kasahara, K. Fukunaga, and E. Miyamoto
Activation of Calcium/Calmodulin-dependent Protein Kinase IV in Long Term Potentiation in the Rat Hippocampal CA1 Region
J. Biol. Chem.,
June 22, 2001;
276(26):
24044 - 24050.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
