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The Journal of Neuroscience, October 1, 1999, 19(19):8292-8299
Differential Roles of Ca2+/Calmodulin-Dependent
Protein Kinase II and Mitogen-Activated Protein Kinase Activation in
Hippocampal Long-Term Potentiation
Jie
Liu,
Kohji
Fukunaga,
Hideyuki
Yamamoto,
Katsuhide
Nishi, and
Eishichi
Miyamoto
Department of Pharmacology, Kumamoto University School of Medicine,
Kumamoto 860-0811, Japan
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ABSTRACT |
The roles of Ca2+/calmodulin-dependent protein
kinase II (CaM kinase II) and mitogen-activated protein kinase (MAPK)
in long-term potentiation (LTP) were investigated in the CA1 area of
hippocampal slices, using electrophysiological and biochemical
approaches. A brief high-frequency stimulation, but not low-frequency
stimulation, delivered to Schaffer collateral/commissural afferents
produced a stable LTP and activated both CaM kinase II and 42 kDa MAPK. Different from the activity of CaM kinase II, the increase in MAPK
activity was transient. At a concentration of 50 µM, but not of 30 µM,
PD098059, a potent inhibitor of MAPK kinase, markedly inhibited the
induction of LTP. Although the two concentrations had similar
inhibitory effects on MAPK activity, only 50 µM PD098059 suppressed the activation of CaM kinase II. Application of
calmidazolium, an antagonist of calmodulin, blocked both CaM kinase II
activation and the LTP induction without affecting the increase in 42 kDa MAPK activity. Application of neurotrophin brain-derived
neurotrophic factor (BDNF) promoted the induction of LTP, with
concomitant activation of CaM kinase II. Under the same conditions,
BDNF failed to activate MAPK in hippocampal slices. These results
indicate that, although the LTP induction is accompanied by increases
in two kinase activities, only CaM kinase II activation is required for
this event.
Key words:
LTP; CaM kinase II; MAPK; hippocampal slice; PD098059; synaptic plasticity
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INTRODUCTION |
Long-term potentiation (LTP) is
considered to be a model of synaptic plasticity that may underlie
memory and learning (Bliss and Collingridge, 1993 ; Malenka and Nicoll,
1993). Although the exact biochemical processes and molecular
mechanisms remain unclear, several lines of evidence have shown that
certain protein kinases are involved in LTP. A multifunctional
Ca2+/calmodulin-dependent protein kinase
II (CaM kinase II) in the brain has been intensively researched and was
found to play a critical role in the induction of hippocampal LTP
(Lisman and Goldring, 1988; Malinow et al., 1989; Malenka et al., 1989;
Silva et al., 1992; Lledo et al., 1995; Miyamoto and Fukunaga, 1996; Barria et al., 1997). In the previous studies, we demonstrated that
tetanic stimuli-induced LTP leads to a persistent increase in CaM
kinase II activity in hippocampal slices (Fukunaga et al., 1993)
accompanied with autophosphorylation of the kinase and phosphorylation of presynaptic and postsynaptic proteins (Fukunaga et al., 1995). This
view has been confirmed by Ouyang et al. (1997), who visualized an
increase in autophosphorylation of CaM kinase II in hippocampal slices
after tetanic stimulation.
Recent studies have focused on another attractive protein kinase
family, mitogen-activated protein kinase (MAPK). These enzymes may
regulate a wide array of cellular processes (Roberts, 1992; Xia et al.,
1996). In response to extracellular stimuli, such as growth factors,
neurotrophins, and neurotransmitters, MAPK is activated by
phosphorylation on both threonine and tyrosine residues (Bading and
Greenberg, 1991; Seger and Krebs, 1995). In addition, the neuronal
activity-dependent activation of 42 kDa MAPK has been reported by three
groups of researchers, who demonstrated that high KCl pulse (Baron et
al., 1996), electroconvulsive shock (Kang et al., 1994), or tetanic
stimuli (English and Sweatt, 1996) induce increases in MAPK activity in
the hippocampus. More recently, Atkins et al. (1998) reported that MAPK
activity increased in the hippocampus during fear conditioning.
Furthermore, studies using a pharmacological inhibitor showed that the
MAPK translocation and signal cascade are required for LTP (English and
Sweatt, 1997; Martin et al., 1997). However, the inhibition of synaptic
potentiation in Aplysia neurons (Martin et al., 1997) and
hippocampal slices (English and Sweatt, 1997) was mainly obtained,
using a compound PD098059, an inhibitor for MAPK kinase (MEK) (Alessi
et al., 1995), in which CaM kinase II activity was not detected.
Because our previous work showed that not only CaM kinase II but also
42 kDa MAPK was activated by stimulation of glutamate receptors with
NMDA or glutamate (Fukunaga et al., 1992; Kurino et al., 1995; Fukunaga
and Miyamoto, 1998) in cultured hippocampal neurons, we asked if MAPK
activity also contributes as CaM kinase II does to regulation of
synaptic plasticity. Here, we used in-gel kinase assay to
simultaneously explore changes in activities of CaM kinase II and MAPK
in hippocampal slices. We found that, although a brief high-frequency
stimulation (HFS) produced increases in both 42 kDa MAPK and CaM kinase
II activities, only CaM kinase II activation directly correlates with
hippocampal LTP induction.
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MATERIALS AND METHODS |
Materials. The chemicals and reagents we used were
obtained from the following sources:
 -[32P]ATP, DuPont NEN, Boston, MA;
PD098059, Research Biochemicals, Natick, MA; calmidazolium
(R24571), Sigma, St. Louis, MO; autocamtide-2-related inhibitory
peptide, Bachem; and human recombinant brain-derived neurotrophic
factor (BDNF), Calbiochem, La Jolla, CA. BDNF was dissolved in
phosphate buffer (100 µg/ml) and stored at  30°C. Before every
experiment, the stock solution was diluted with artificial CSF (ACSF)
to the final concentration. PD098059 and calmidazolium were first
dissolved in dimethylsulfoxide (DMSO) and then added to the ACSF
perfusion. The final concentration of the solvent in the medium was
kept at <0.01%. To ensure the complete solubility of the drugs, ACSF
solutions were maintained at 32°C. The vehicle alone had no apparent
effect on synaptic responses. Myelin basic protein (MBP) was purified
from bovine brain (Deibler et al., 1972).
Preparation of hippocampal slices and electrophysiology.
After decapitation, brains of male Sprague Dawley rats (~5-8 weeks old) were rapidly removed, and the hippocampus was dissected out. Transverse hippocampal slices (450 µm thickness), prepared using a
McIlwain tissue chopper, were incubated in continuously oxygenated ACSF, at room temperature and for at least 2 hr. The composition of
ACSF contained (in mM): NaCl, 124; KCl, 3;
CaCl2, 2.5; MgCl2, 1.5;
NaH2PO4, 1.25;
NaHCO3, 26; D-glucose, 10 (gassed
with 95% O2 ± 5% CO2, pH
7.4). After a 2 hr recovery period, a slice was then transferred to an
interface recording chamber and perfused at a flow rate of 2 ml/min
with ACSF warmed at 32°C. The field EPSP (fEPSP) was evoked by 0.033 Hz test pulses through a bipolar stimulating electrode (twisted, 50 µm insulated tungsten wire) placed on the Schaffer
collateral/commissural pathway, and recorded from the stratum radiatum
of CA1 using a glass micropipette electrode filled with 3M
NaCl. The stimulus intensity was adjusted to evoke a fEPSP of ~1.5 mV
amplitude, and the responses were monitored for at least 20 min to
ensure a stable baseline. Then, this stimulus strength was maintained
at the same level before and during the period of drug preincubation
until each experiment was finished. LTP was induced by strong HFS,
which consists of two 100 Hz, 1 sec trains delivered 20 sec apart.
Low-frequency stimulation (LFS) which did not induce synaptic
potentiation consisted of 20 pulses at 20 Hz. Shorter HFS (SHFS), a
subthreshold stimulation for LTP induction, was applied at 100 Hz, 13 pulses to produce short-term potentiation (STP). After
electrophysiological recording and stimulation, the slices were
transferred to a glass slide at ice temperature, and the CA1 areas were
dissected out and stored at 80°C until assay.
Autophosphorylation of CaM kinase II. Autophosphorylation of
purified CaM kinase II was carried out at 0°C for 20 min. The reaction mixture contained 50 mM HEPES buffer, pH 7.5, 10 mM Mg2+, 0.2 mM
Ca2+, 1 µM calmodulin, and
50 µM ATP, and 3 µg of CaM kinase II in a total volume
of 100 µl. After incubation for 20 min, the reaction was terminated
by adding Laemmli's sample solution.
Sample preparation. Hippocampal slice samples for kinase
assay were prepared as previously described (Kurino et al., 1995; Fukunaga and Miyamoto, 1998). Briefly, the CA1 subregion from individual slices was homogenized at 4°C by sonication in
solubilizing buffer containing 0.1% Triton X-100, 50 mM
HEPES, 4 mM EGTA, 10 mM EDTA, 15 mM
Na4P2O7,
100 mM  -glycerophosphate, 25 mM NaF, 0.1 mM leupeptin, 50 µg/ml trypsin inhibitor, 75 µM pepstatin A, 100 nM calyclin A, 1 mM sodium orthovanadate, and 1 mM
dithiothreitol, pH 7.4. The insoluble material was removed by
centrifugation at 15,000 × g for 5 min at 4°C, and
the aliquots (5 µl) were used to determine protein content. Then,
Laemmli's sample buffer was added to supernatant fraction, and the
samples were boiled at 100°C for 5 min.
Protein kinase assay. MAPK and CaM kinase II activities were
determined by using in-gel kinase assay method of Geahlen et al.
(1986), Kameshita and Fujisawa (1989), and Gotoh et al. (1990) with
some modifications. Briefly, as a substrate for phosphorylation with
kinases, MBP (0.5 mg/ml) was added to the separating SDS-PAGE before polymerization of acrylamide. Cell lysates (15-20 µg of protein/lane) were separated by 10% SDS-PAGE. After electrophoresis, SDS was removed by washing the gel with 20% 2-propanol in 50 mM Tris-HCl buffer, pH 7.5. Then, the gel was treated with
6 M guanidine HCl to denature the enzyme for 1 hr, followed
by renaturation in 50 mM Tris-HCl buffer, pH 7.5, containing 0.04% Triton X-100, 5 mM mercaptoethanol, and
0.1 mM sodium orthovanadate for 16 hr at 4°C. After
renaturation, the gel was preincubated at 22°C for 1 hr with 10 ml 40 mM HEPES buffer, pH 8.0, containing 2 mM
dithiothreitol, 10 mM MgCl2, and 0.1 mM sodium orthovanadate. Phosphorylation of MBP was carried
out by incubating the gel at 22°C for 1 hr with 10 ml 40 mM HEPES buffer, pH 8.0, containing 0.5 mM
EGTA, 10 mM MgCl2, 0.1 mM
sodium orthovanadate, and 40 µM
-[32P] ATP (25 µCi). The gel was
then rinsed with 5% (w/v) trichloroacetic acid solution containing 1%
sodium pyrophosphate to remove noncovalently bound
32P. Thereafter, the gel was dried, and
the amount of 32P incorporation into MBP
in the gel was quantified by a Bio-Imaging analyzer (BA100; Fujifilm,
Tokyo, Japan) to determine the kinase activity.
Immunoprecipitation of CaM kinase II. Hippocampal slice cell
lysates were prepared as described under "Sample preparation". After centrifugation, the supernatant fraction was incubated with active-specific CaM kinase II antibody (10 µg of IgG protein) and 40 µl of protein A-Sepharose CL-4B suspension (50% v/v) at 4°C for 4 hr. After incubation, the immunocomplex immobilized on protein A was
precipitated by centrifugation at 12,000 × g for 5 min. The immunocomplex was washed four times with a buffer containing
0.1% Triton X-100, and in mM: 50 HEPES, 4 EGTA,
10 EDTA, 15 Na4P2O7,
100 -glycerophosphate, and 25 NaF. Laemmli's sample buffer was
added to the supernatant fraction and the immunocomplex, and then the
samples were boiled at 100°C for 5 min before application to
SDS-PAGE.
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RESULTS |
Identification of CaM kinase II and MAP kinase activities in
MBP-contained polyacrylamide gels
To determine the activities of CaM kinase II and MAPK in
hippocampal slices, we performed an in-gel kinase assay by using MBP as
a good exogenous substrate for MAPK (Gotoh et al., 1990) as well as for
CaM kinase II (Gupta et al., 1992). This method has been shown to be
sensitive and useful for detection of a variety of protein kinases in
complex mixtures (Geahlen et al., 1986; Kameshita and Fujisawa, 1989).
Five major bands were detected in the hippocampal slices (Fig.
1A). Among them, the
band that matched CaM kinase II was identified by applying the purified CaM kinase II onto the gel. As shown in Figure 1A,
the topmost band of hippocampal slice samples were seen to coincide
with the purified CaM kinase II (lane 9).
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Figure 1.
Identification of CaM kinase II and MAPK
activities in MBP-contained polyacrylamide gels. A,
Autoradiographs of in-gel kinase assay. Lanes 1,
2, 7, and 8, Immunocomplexes from hippocampal
slices incubated with (lanes 1 and 8) and
without (lanes 2 and 7)
anti-active CaM kinase II antibody; lanes 3-6,
supernatants of the hippocampal slices after immunoprecipitation of CaM
kinase II. Each sample was immunoprecipitated in the presence
(lanes 3 and 5) and absence (lanes
4 and 6) of anti-active CaM kinase II
antibody before application to SDS-PAGE. Lane 9,
Autophosphorylation assay for purified CaM kinase II (1 µg) in the
presence of Ca2+/calmodulin. B, Two
lower bands corresponded to MAPK isoforms of 42 and 44 kDa and were
markedly suppressed by 50 µM PD098059.
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To gain further insight into the nature of the band of CaM kinase II in
in-gel kinase assay, we next performed an experiment on
immunoprecipitation of CaM kinase II in LTP-established and control
slices. As seen in Figure 1A, samples of control and
LTP slices were immunoprecipitated with anti-active CaM kinase II antibody or with the buffer lacking the antibody before separation by
SDS-PAGE. The band of CaM kinase II was strongly detected in the
antibody-untreated LTP (Fig. 1A, lane
6) but not in the control supernatant sample (Fig.
1A, lane 4), whereas the
solubilized CaM kinase II was much less visualized in anti-active CaM
kinase II-treated LTP sample (Fig. 1A, lane
5), indicating that the band was able to be absorbed by
anti-active CaM kinase II antibody. When the immunocomplexes were
applied to SDS-PAGE, followed by autoradiography, the antibody-treated
LTP (Fig. 1A, lane 8) and control (Fig.
1A, lane 1) samples appeared to be
detected in a band corresponding to CaM kinase II. Thus, changes in
intensity of the topmost band may reflect a change in activity of CaM
kinase II in slices, although the possibility is not excluded that a little activity of other unidentified kinase was present on background.
Two lower bands that corresponded to MAPK isoforms of 42 and 44 kDa had
certainly been identified by Gotoh et al. (1990) and Kurino et al.
(1995). Both bands were markedly suppressed by 50 µM
PD098059, a specific inhibitor of MEK (Fig. 1B). In
the following experiments, we used this approach to assay activities of
autonomous CaM kinase II and MAPK in CA1 areas.
Transient activation of 42 kDa MAPK during LTP induction
In a previous study, we showed that stimulation of glutamate
receptors by treatment with NMDA or glutamate produced a transient increase in 42 kDa MAPK activity as well as the
Ca2+-independent form of CaM kinase II
(Fukunaga et al., 1992; Kurino et al., 1995; Fukunaga and Miyamoto,
1998) in cultured hippocampal neurons, whereas in the hippocampal
slices, HFS resulted in a long-lasting increase in activity of CaM
kinase II (Fukunaga et al., 1993). These observations suggest that the
activation of protein kinases can be regulated in an activity-dependent
manner. A Western blotting study showed that 2 min after delivering HFS to Schaffer collateral pathway in hippocampal slices, the 42 kDa MAPK
activity increased, and this activation was not persistent during the
entire period of LTP induction (English and Sweatt, 1996, 1997). To
confirm this result, we therefore investigated changes in MAPK activity
in dissected CA1 areas of hippocampal slices, before and after HFS
delivery. Figure 2 shows the time course
of MAPK activities, under different conditions. Immediately after HFS,
substantial increases in the activity of 42 kDa MAPK, but not 44 kDa
MAPK were evident in LTP-established slices. A peak increase of
38.6 ± 3.7% (n = 8) in kinase activity was
observed at 3 min after HFS, followed by a rapid recovery at 10 min and then reverting to nearly basal levels after 30 min. This result is
similar to that reported by other investigators (English and Sweatt,
1996). However, in slices subjected to LFS, no increase in MAPK
activity was observed (n = 6).
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Figure 2.
LTP induction is accompanied by a transient
increase in 42 kDa MAPK but not 44 kDa MAPK activity. A,
Electrophysiological recordings illustrate the average changes in
synaptic efficacy in CA1 area of hippocampal slices
(n = 12) produced by HFS. Average fEPSP amplitude
for each time point was normalized to the average baseline response
before HFS. Inset, Representative traces before and 1 hr
after HFS. B, Normalized fEPSP amplitude from
LFS-received slices. Inset, Representative traces before
and 1 hr after LFS. C, Time course of 42 kDa MAPK
activation in the slices treated with HFS or LFS. Top
panel shows an autoradiograph of in-gel kinase assay for the
time course of HFS-induced MAPK activity. Results are expressed as
percentages of the activity in control slices at zero time. Data are
mean ± SE values. The changes in the MAPK activity were
statistically significant versus the control: **p < 0.01.
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Concentration-dependent inhibitory effects of PD098059 on LTP
It has been well documented that the phosphorylation of MAPK is
regulated by MEK, the MAPK kinase, which occurs upstream of MAPK. Thus,
to test the physiological role of 42 kDa MAPK in LTP, we used the
specific inhibitor of MEK, PD098059, to indirectly abolish the
activation of MAPK. In the LTP experiments, we first used a relatively
higher concentration of 50 µM PD098059 because ~90%
blocking effect on MAPK has been observed with use of this concentration (English and Sweatt, 1997). Before HFS delivery, PD098059
was applied to slices for 90 min in the preincubation period. During
the drug application, we found no change in basal synaptic transmission
of the slices (data not shown). In contrast, the potentiation of fEPSP
after HFS delivery significantly decayed to nearly basal levels after
60 min in slices pretreated with 50 µM PD098059 (Fig.
3A; n = 9),
whereas a stable LTP was maintained for >1 hr in control slices
(Fig. 3A; n = 12). However, at a
concentration of 30 µM, the drug
preincubation for the same period of 90 min did not attenuate the
induction of LTP (Fig. 3B; n = 6). These results suggest that the inhibitory effect of PD098059 on LTP was
concentration-dependent.
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Figure 3.
PD098059 caused concentration-dependent
inhibitions of both LTP induction and CaM kinase II activation in CA1
areas. A, Compared with the control slices (open
triangles; n = 12), preincubation of slices
with 50 µM PD098059 markedly prevented HFS-sensitive
induction of hippocampal LTP (filled triangles;
n = 9). Average amplitude of fEPSP for each point
was normalized to the average responses of baseline before HFS.
B, At a lower concentration of 30 µM,
PD098059 did not affect the induction of LTP (n = 6). C, Analysis of CaM kinase II and MAPK activities in
the slices treated with different concentrations of PD098059.
Left panel shows a representative autoradiograph of
in-gel kinase assay for kinase activities. Right diagram
illustrates statistical data. In HFS-receiving slices, kinase activity
was assayed at 3 min after HFS. At 50 µM
(n = 9), PD098059 suppressed both 42 and 44 kDa
MAPK activity and prevented HFS-induced CaM kinase II activation. At 30 µM (n = 6) of the drug, only MAPK, not
CaM kinase II was inhibited. Data are expressed as mean ± SE
values. **p < 0.01.
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Inhibitory effects of PD098059 on CaM kinase II and MAPK activation
in response to LTP-inducing HFS
As described above, at concentrations of 30 and 50 µM, PD098059 appeared to have different effects on the
LTP induction. To determine if the lack of inhibitory effect seen with
30 µM is caused by the weak blocking action of the drug
on the activation of MAPK, we next examined effects of PD098059 on
protein kinase activity in the hippocampal slices. Because a maximal
increase in MAPK activity was observed at 3 min after HFS (Fig.
2B), we designed an experimental protocol of
collecting slices at 3 min after HFS to direct attention to this time
point. In PD098059-treated slices, the activities of both 44 and 42 kDa
MAPK were markedly inhibited by the drug (Fig. 3C). The
extent of 42 kDa MAPK inhibition, expressed as a percentage of the
control, was 40 ± 3.1% at 30 µM
(n = 6) and 48 ± 4.3% at 50 µM (n = 9). Thus, at both
concentrations, PD098059 similarly inhibited the HFS-induced transient
activation of 42 kDa MAPK. These observations indicate that the effect
of 50 µM PD098059 on LTP induction could not be
simply explained by inhibitory effects of the drug on MAPK.
We then analyzed the changes in CaM kinase II activity detectable in
the same gel. With the same protocol for MAPK assay, CaM kinase II
activity was also examined at a time point of 3 min after HFS. In
Figure 3C, the topmost band, which corresponds to CaM kinase
II is so different in the presence of 30 or 50 µM PD098059. When the drug was applied at 50 µM, HFS did not produce any significant
increase in CaM kinase II activity in the slices in which HFS failed to
elicit the LTP. In contrast, in slices pretreated with 30 µM PD098059, a brief HFS markedly activated CaM
kinase II as well as LTP. Statistical analysis showed that HFS delivery
produced an increase of 78.6 ± 15.3 (n = 8) in
CaM kinase II activity under condition of 30 µM
drug treatment, whereas no significant increase was detectable in 50 µM drug-treated slices (n = 9).
Thus, in addition to MEK, its downstream target, PD098059, also has
inhibitory effects on CaM kinase II activation of hippocampal slices.
A question arose here as to whether this effect occurs by directly
inhibiting activity of CaM kinase II. To answer this question, we next
tested the effect of PD098059 on the activity of purified CaM kinase II
in vitro. At concentrations of 10, 50, and 100 µM, PD098059 did not affect the activity of
this kinase (data not shown), suggesting that PD098059 has no direct
inhibitory effect on CaM kinase II.
Effects of calmidazolium on the activation of CaM kinase II and 42 kDa MAPK in LTP
CaM kinase II is a
Ca2+/calmodulin-stimulated target enzyme.
Because both Ca2+ influx and calmodulin
activation are prerequisite for switching the kinase
autophosphorylation, their inhibitors are capable of blocking
activation of the kinase. Calmidazolium, a potent calmodulin antagonist
that does not influence Ca2+ flux and PKC
activity (Reymann et al., 1988), has been shown to block
calmodulin-mediated LTP (Reymann et al., 1988; Fukunaga et al., 1995).
Here, we repeated the experiments of calmidazolium on LTP and analyzed
changes in activities of CaM kinase II and MAPK in the CA1 area of
hippocampal slices. In accordance with our previous report, incubation
of hippocampal slices with 50 µM calmidazolium for 1 hr
strongly blocked post-tetanic potentiation and LTP induction (Fig.
4C), whereas basal synaptic
transmission and HFS-mediated depolarization were not affected (Fig.
4A,B). The assay for protein kinase activity was then
performed in HFS-received slices under calmidazolium-treated and
untreated conditions, respectively. Slice samples for protein kinase
assay were collected at 3 min after HFS. Compared with the
LTP-established slices, in which both CaM kinase II and MAPK activities
increased, bath-application of 50 µM
calmidazolium suppressed the activation of CaM kinase II that responded
to HFS. However, delivery of the same HFS still produced a transient
increase in MAPK activity from the control level to a higher activity
of 132 ± 5.9 (n = 5), even in
calmidazolium-treated slices (Fig. 4B). These results
suggest that HFS-induced activation of MAPK per se may not lead to LTP
induction.
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Figure 4.
Calmidazolium blocked the induction of LTP without
affecting basal synaptic transmission, HFS-mediated depolarization, and
HFS-induced 42 kDa MAPK activation. A, Normalized fEPSP
amplitudes recorded before and during continuous calmidazolium
application (n = 6). No change in basal synaptic
transmission of the slices was found. B, Partial display
of representative HFS-mediated depolarization responses in control and
calmidazolium-treated slices. Calmidazolium had no effect on
HFS-mediated depolarization. C, Normalized fEPSP
amplitudes recorded before and after HFS. Pretreatment of slices with
50 µM calmidazolium for 1 hr strongly blocked the
formation of LTP (filled triangles;
n = 5). D, Kinase assay for
activities of CaM kinase II and 42 kDa MAPK at 3 min after HFS. Both
activities of CaM kinase II and 42 kDa MAPK increased in LTP-inducing
slices (n = 8), whereas application of
calmidazolium (50 µM) blocked HFS-induced increase in the
activity of CaM kinase II but not of 42 kDa MAPK (n = 5). **p < 0.01. Calibration: 1 mV, 70 msec.
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Strengthening the LTP induction and CaM kinase II activation by
exogenous BDNF
It has been proposed that neurotrophic factors can regulate
neuronal activity and synaptic efficacy via the activation of TrK
family of tyrosine kinase receptors (Kang and Schuman, 1995; Levine et
al., 1995; Figurov et al., 1996; Akaneya et al., 1997). One of these
factors, BDNF, is synthesized predominantly in neurons, and is highly
expressed in the hippocampus of the adult species brain. The binding of
BDNF to the TrKB receptor triggers the kinase cascade and thereby
activates MAPK in culture neurons (Finkbeiner et al., 1997; Fukunaga
and Miyamoto, 1998). We then used BDNF as a modulator for MAPK to
further explore the role of MAPK in LTP in hippocampal slices. As shown
in Figure 5A, application of
50 ng/ml BDNF alone did not affect basal synaptic strength under our
experimental conditions. This result is similar to that reported by
Figurov et al. (1996) and by Gottschalk et al. (1998), which is
contradictory to observations that BDNF induced a long-lasting enhancement of synaptic transmission (Kang and Schuman, 1995). Possible
explanation for the discrepancy has been proposed by Kang et al.
(1996), who reported that the perfusion rate is critical for the
penetration of BDNF into the hippocampal slices. In Figure 5C, subthreshold SHFS induced only an STP of fEPSP in
control slices. However, when slices were preincubated with 50 ng/ml
BDNF for >2 hr, the same SHFS triggered a typical LTP that lasted for >1 hr. This result is consistent with previous findings (Figurov et
al., 1996).
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Figure 5.
BDNF promoted the induction of LTP and the
activation of CaM kinase II without affecting basal synaptic
transmission and MAPK activity. A, Normalized fEPSP
amplitudes recorded before and during continuous application of 50 ng/ml BDNF (n = 6). BDNF alone did not affect basal
synaptic strength of slices. B, Representative
autoradiograph of MAPK activity assay in control and BDNF application
slices. BDNF treatment did not result in MAPK activation.
C, The fEPSP potentiation induced by a subthreshold SHFS
in control (open triangles; n = 8)
and BDNF-pretreated slices (filled triangles;
n = 6). After 2 hr preincubation with BDNF (50 ng/ml), SHFS delivery converted STP to LTP. D, Kinase
assay for CaM kinase II and MAPK activity in the presence or absence of
BDNF. In contrast to control slices, the activity of CaM kinase II was
increased in the slices treated with BDNF for 2 hr
(n = 6), whereas no change in activity of MAPK was
detectable. This effect was facilitated by delivering SHFS3
(n = 6). **p < 0.01. An
autoradiograph of kinase activities is shown in the left
panel.
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It has been shown that BDNF rapidly stimulates both 41 and 44 kDa MAPK
with a time course reaching a maximum at 2 min and then returning
toward baseline slowly over the next 60 min in cultured hippocampal
pyramidal neurons (Marsh et al., 1993). To clarify whether the MAPK
cascade is involved in BDNF-enhanced LTP, we measured the kinase
activity in slices in the presence and absence of BDNF. We found no
changes in both 44 and 42 kDa MAPK activity in BDNF-treated slices
during the period of incubation with 50 ng/ml BDNF for 3, 10, 30, 60, and 120 min (Fig. 5B), except for a significant increase in
activity of CaM kinase II at 2 hr (25 ± 7.7%; n = 6; Fig. 5D). Furthermore, delivery of SHFS to 2 hr
BDNF-treated slices resulted in a further increase in CaM kinase II
activity (43.4 ± 6.7%; n = 6; Fig.
5D), which was detected at 3 min after SHFS
(SHFS3). Based on these results, it seems unlikely that the effects of BDNF on SHFS-induced fEPSP potentiation are related to the activation of MAPK. Because the increase in activity
of CaM kinase II is produced by BDNF, one can predict that the most
possible candidate for LTP induction is CaM kinase II.
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DISCUSSION |
In the present study, using both electrophysiological and
biochemical approaches we demonstrated that the induction of LTP is
dependent on CaM kinase II activity rather than on MAPK activity in CA1
hippocampal slices. The transient activation of 42 kDa MAPK in
HFS-receiving slices supports the view of activity-dependent regulation
of this enzyme. A most interesting finding in our experiments is that
we observed a heretofore unknown pharmacological effect of PD098059
that is commonly believed to be a specific inhibitor of MAPK kinase.
Although earlier studies examined effects of this agent on a variety of
protein kinases and found that only MAPK kinase is sensitive to it
(Alessi et al., 1995; Dudley et al., 1995), information about its
effect on CaM kinase II was not allied. Most recently, one research
group suggested that MAPK activation is necessary for LTP because they
found an inhibitory effect of PD098059 on LTP (English and Sweatt,
1997). In that paper, the authors said that they tested the effect of
PD098059 on the activity of CaM kinase II in vitro and found
no definite actions. This is consistent with our results. However, when
we used it in HFS-induced slices, the data clearly showed that 50 µM PD098059 actually blocked HFS-induced
activation of CaM kinase II in hippocampal slices. A similar result was
also found in cultured hippocampal neurons (data not shown). This
evidence suggests that there is an indirect effect of this compound on
CaM kinase II, differing from its effect of binding to inactive form of
MEK (Alessi et al., 1995), although the precise blocking mechanisms are
unknown. Recently, PD098059 has been found to have a direct inhibitory
effect on cyclooxygenase-1 and -2 (Borsch-Haubold et al., 1998).
Therefore, one must be careful when using this drug as an MEK inhibitor
at concentrations  50 µM.
Additionally, these findings also suggest that the inhibition of
hippocampal LTP induction with PD098059 was caused by its effects on
CaM kinase II and not on the MEK/MAPK pathway. The parallel changes in
hippocampal LTP and CaM kinase II activity indicate that CaM kinase II
activation plays a critical role in LTP induction.
Recent studies have shown that the expression of BDNF is regulated by
neuronal activity (Castren et al., 1992; Patterson et al., 1992;
Dragunow et al., 1993) and that the synaptic efficacy and LTP induction
were promoted by exogenous BDNF (Kang and Schuman, 1995; Figurov et
al., 1996). Thus, BDNF may be a mediator of neuronal adaptive
responses. Consistent with these findings, our data showed that BDNF
enhanced the sensitivity of synapses to respond to SHFS. This effect
may be caused by activation of CaM kinase II rather than to that of
MAPK, because the active form of CaM kinase II alone has been found to
be sufficient to augment synaptic strength with the same mechanism as
LTP (Lledo et al., 1995), and BDNF can activate CaM kinase II without
affecting MAPK activity in hippocampal slices. Other reports have
recently shown that BDNF-induced CaM kinase II activation is dependent
on a pathway of PLC and intracellular
Ca2+ release (Blanquet and Lamour, 1997;
Finkbeiner et al., 1997). Therefore, BDNF may be involved in the
Ca2+/CaM-dependent kinase-mediated cascade
of events that results in LTP construction. On the other hand, it has
been proposed that a transcription factor, cAMP response
element-binding protein (CREB), plays a key role in mediating
neurotrophin responses because BDNF can activate CREB through a CaM
kinase-dependent mechanism, and also BDNF itself can be regulated by a
Ca2+/CaM kinase/CREB-dependent mechanism
(Tsuda, 1996; Finkbeiner et al., 1997; Shieh et al., 1998; Tao et al.,
1998). Therefore, the involvement of BDNF in the CaM kinase signaling
cascade is important for the self control of the neuronal functions,
including synaptic plasticity.
In addition to cytosolic localization, CaM kinase II was particularly
enriched in postsynaptic densities (PSD), specializations of
submembranous cytoskeleton that are believed to participate in the
regulation of receptor function, structural modification, and synaptic
plasticity (Kennedy et al., 1983; Wu et al., 1992; Kennedy, 1993). CaM
kinase II in the PSD possesses regulatory properties and mechanisms of
activation similar to the cytosolic CaM kinase II (Rich et al., 1989).
Under our experimental conditions, only the soluble kinases were
analyzed. However, our previous paper has demonstrated that >95% of
CaM kinase II activity remained in the supernatant fraction (Fukunaga
et al., 1993, 1995), i.e., only 5% of CaM kinase II activity was
present in Triton X-100-insoluble cytoskeletal fraction, including PSD
in hippocampal slices, which is consistent with the fact that most of
CaM kinase II in the PSD is largely inactive (Rostas et al., 1986).
Studies on association of soluble CaM kinase II with PSD showed that
cytosolic CaM kinase II is reversibly translocated to the PSD and forms
PSD-CaM kinase II complex in a phosphorylation-dependent manner
(Yoshimura and Yamauchi, 1997).The translocated CaM kinase II may be
collected in the Triton X-100-soluble fraction. When calcium influx
increases in postsynapse, the cytosolic CaM kinase II is
autophosphorylated and activated and then translocated to the PSD.
Furthermore, other groups reported that the active CaM kinase II
phosphorylates GluR1 and other functional proteins in PSD, resulting in
an enhancement of postsynaptic response as occurs during LTP
(McGlade-McCulloh et al., 1993). Thus, translocation of the soluble CaM
kinase II to PSD in response to HFS-induced calcium influx was
considered to be involved in LTP induction (Strack et al., 1997). In
contrast to CaM kinase II in PSD, although 42 kDa MAPK and MAPK kinase were also found to be present in PSD (Suzuki et al., 1995), the roles
of PSD-bound MAPK in regulation of synaptic response have not yet been surveyed.
Our results show that LTP-inducing electric stimuli rapidly increase
the 42 kDa MAPK activity, and 50 µM PD098059 clearly inhibits the induction of LTP. However, we cannot say that MAPK activation is required for the LTP induction because inhibiting MAPK
activity by 30 µM PD098059 did not affect the LTP
expression. As MAPK participates in regulating diverse cellular
processes, especially in gene transcription such as Elk-1 (Xia et al.,
1996) and CREB transcriptional pathways (Xing et al., 1996; Finkbeiner et al., 1997), the activity-dependent activation of MAPK may underlie some important neurophysiological functions. Although we stated that
the LTP induction cannot be attributed to MAPK activation, the
maintenance of LTP cannot be excluded as the potential target of this
kinase, because protein synthesis and gene expression are required for
the late phase of LTP (Winder et al., 1998). Extensive studies are
needed for understanding the signaling meaning of HFS-induced MAPK
activation on the maintenance of LTP.
| |
FOOTNOTES |
Received July 19, 1999; accepted July 21, 1999.
This work was supported in part by Grants-in-Aid for Scientific
Research and for Scientific Research on Priority Areas from the
Ministry of Education, Science, Sports, and Culture of Japan, and by a
Research Grant from the Human Frontier Science Program. We thank Dr. H. Nakanishi and Prof. K. Yamamoto, Department of Pharmacology, Kyushu
University Faculty of Dentistry, for technical advice.
Correspondence should be addressed to Prof. Eishichi Miyamoto,
Department of Pharmacology, Kumamoto University School of Medicine, 2-2-1 Honjo, Kumamoto 860-0811, Japan.
| |
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Coactivation of beta -Adrenergic and Cholinergic Receptors Enhances the Induction of Long-Term Potentiation and Synergistically Activates Mitogen-Activated Protein Kinase in the Hippocampal CA1 Region
J. Neurosci.,
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[Abstract]
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L. Lhuillier and S. E. Dryer
Developmental Regulation of Neuronal KCa Channels by TGFbeta 1: Transcriptional and Posttranscriptional Effects Mediated by Erk MAP Kinase
J. Neurosci.,
August 1, 2000;
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[Abstract]
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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.,
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[Abstract]
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G.-Y. Wu, K. Deisseroth, and R. W. Tsien
Activity-dependent CREB phosphorylation: Convergence of a fast, sensitive calmodulin kinase pathway and a slow, less sensitive mitogen-activated protein kinase pathway
PNAS,
February 27, 2001;
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2808 - 2813.
[Abstract]
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S. M. Dudek and R. D. Fields
Mitogen-Activated Protein Kinase/Extracellular Signal-Regulated Kinase Activation in Somatodendritic Compartments: Roles of Action Potentials, Frequency, and Mode of Calcium Entry
J. Neurosci.,
January 15, 2001;
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ABSTRACT
INTRODUCTION
Compound via MeSH
