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The Journal of Neuroscience, January 1, 2001, 21(1):143-149
Presynaptic Role of cGMP-Dependent Protein Kinase during
Long-Lasting Potentiation
Ottavio
Arancio1,
Irina
Antonova1,
Stepan
Gambaryan2,
Suzanne M.
Lohmann2,
Jason S.
Wood3,
David S.
Lawrence3, and
Robert D.
Hawkins1, 4
1 Center for Neurobiology and Behavior, Columbia
University, New York, New York 10032, 2 Institute of
Clinical Biochemistry and Pathobiochemistry, University of
Wuerzburg, 97080 Wuerzburg, Germany, 3 Department of
Biochemistry, Albert Einstein College of Medicine, Bronx, New York
10461, and 4 New York State Psychiatric Institute, New
York, New York 10032
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ABSTRACT |
Previous research has suggested that cGMP-dependent protein kinases
(cGKs) may play a role in long-term potentiation in hippocampus, but
their site of action has been unknown. We examined this question at
synapses between pairs of hippocampal neurons in dissociated cell
culture. Injection of a specific peptide inhibitor of cGK into the
presynaptic but not the postsynaptic neuron blocked long-lasting potentiation induced by tetanic stimulation of the presynaptic neuron.
As controls, injection of a scrambled peptide or a peptide inhibitor of
cAMP-dependent protein kinase into either neuron did not block
potentiation. Conversely, injection of the  isozyme of cGK type I
into the presynaptic but not the postsynaptic neuron produced
activity-dependent potentiation that did not require NMDA receptor
activation. Evidence from Western blots, reverse transcription-PCR,
activity assays, and immunocytochemistry indicates that endogenous cGK
type I is present in the neurons, including presynaptic terminals.
These results support the idea that cGK plays an important presynaptic
role during the induction of long-lasting potentiation in hippocampal neurons.
Key words:
presynaptic; cGMP; protein kinase; potentiation; hippocampus; culture
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INTRODUCTION |
The mechanisms of induction and
expression of long-lasting potentiation at hippocampal synapses have
been the subject of long-standing debate (Bliss and Collingridge, 1993 ;
Kullmann and Siegelbaum, 1995). A large body of evidence now supports
the idea that potentiation involves postsynaptic mechanisms (Luscher et
al., 2000), but other evidence suggests that potentiation may also
involve retrograde signaling and a presynaptic increase in transmitter
release (Hawkins et al., 1993; Choi et al., 2000). More specifically,
previous research has suggested that cGMP-dependent protein kinase
(cGK) may function as a presynaptic target of nitric oxide (NO) during the induction of long-term potentiation (LTP) in hippocampus (Hawkins et al., 1998). Bath application of inhibitors of cGK such as
Rp-8-Br-cGMPS or KT5823 can block LTP in hippocampal slices (Zhuo et
al., 1994b; Blitzer et al., 1995; Son et al., 1998), and
relatively selective activators of cGK such as 8-pCPT-cGMP and PET-cGMP
produce activity-dependent long-lasting potentiation that does not
require NMDA receptor activation (Zhuo et al., 1994b; Son et
al., 1998). These results are consistent with the idea that cGK may
play a presynaptic role in LTP, but they do not provide direct evidence
for that hypothesis.
The hippocampal cell culture system provides a good model for studying
presynaptic mechanisms (Bekkers and Stevens, 1990; Malgaroli and Tsien,
1992) because substances injected into the cell body have access to the
presynaptic terminals as well as the postsynaptic dendrites within
minutes (Alder et al., 1992; Popov and Poo, 1992; Arancio et al.,
1996). Furthermore, hippocampal neurons in culture can undergo
long-lasting potentiation with many of the key features of LTP in the
CA1 region of hippocampus in slices or in vivo, including a
requirement for Ca2+ influx through
postsynaptic NMDA receptor channels (Bekkers and Stevens, 1990;
Malgaroli and Tsien, 1992; Arancio et al., 1995, 1996; Diesseroth et
al., 1996; Bi and Poo, 1998; Tao et al., 2000). Arancio et al. (1995)
found that long-lasting potentiation can be induced reliably at
synapses between pairs of hippocampal neurons in culture by
high-frequency stimulation of the presynaptic neuron during brief
removal of Mg2+ from the extracellular
solution, which unblocks the NMDA receptor channels. This procedure is
effective even when both cells are held under ruptured whole-cell
voltage clamp, permitting injection of substances into either neuron.
Further experiments using this method have suggested that, during
induction of the potentiation, a retrograde messenger, NO, is
synthesized in the postsynaptic neuron by a
Ca2+-dependent enzyme, NO-synthase, and
diffuses to the presynaptic terminals, where it produces a long-lasting
increase in transmitter release (O'Dell et al., 1991; Arancio et al.,
1996). NO appears to act by stimulating soluble guanylyl cyclase
leading to the production of cGMP, and injection of cGMP into the
presynaptic (but not the postsynaptic) neuron produces
activity-dependent long-lasting potentiation (Arancio et al., 1995).
However, cGMP might act through several pathways besides cGK, including
cyclic nucleotide-gated channels and phosphodiesterases (Lincoln and Cornwell, 1993), both of which are also present in hippocampal neurons
(Repasko et al., 1993; Kingston et al., 1996; Bradley et al., 1997). We
have therefore now investigated the possible presynaptic role of cGK
during the induction of long-lasting potentiation in hippocampal cell culture.
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MATERIALS AND METHODS |
Electrophysiology. Sprague Dawley rats (Hilltop
Laboratory, Scottdale, PA) were housed and cared for in accordance with
the guidelines of Columbia University. Dissociated cell cultures of hippocampal neurons from postnatal day 1 animals were prepared as
described previously (O'Dell et al., 1991). The bath and electrode solutions were also as described previously (Arancio et al., 1995). We
examined monosynaptic EPSCs between pairs of pyramidal-shaped neurons
7-21 d after plating. Both the presynaptic and postsynaptic neurons
were maintained under ruptured whole-cell voltage clamp throughout the
experiments, and the holding currents and input resistances of both
cells were checked for constancy. EPSCs were evoked once every 10 sec
by applying a 10 msec positive voltage step to the presynaptic neuron
of sufficient amplitude to elicit an inward current in that neuron.
Currents were recorded with an Axopatch 1A and Axopatch 200B (Axon
Instruments, Foster City, CA) and filtered at 1 kHz. EPSC
amplitudes were measured automatically between the peak and the mean
during the interval just before the start of the EPSC using the pClamp
program from Axon Instruments. A peptide inhibitor of cGK
(synthesized at Albert Einstein College of Medicine), a peptide
containing the same amino acids with their sequence scrambled
(synthesized at Columbia University), or a peptide inhibitor of
cAMP-dependent protein kinase (Upstate Biotechnology, Lake Placid, NY)
were included in the presynaptic or postsynaptic electrode solution
throughout the experiments. The isozyme of cGK type I (Promega,
Madison, WI) was delivered to the tip of the electrode by a fast
internal perfusion method that has been described previously (Arancio
et al., 1995). All other chemicals were from Sigma (St. Louis, MO)
unless otherwise indicated. Data are shown as mean ± SEM percent
of the baseline EPSC amplitude. The data were analyzed by a two-way
ANOVA (treatment and time) followed by planned pairwise comparisons of
the treatments overall and at each time point.
Western blotting. Hippocampi microdissected from male
Sprague Dawley rats (150-200 gm, anesthetized with Nembutal) were
homogenized in PBS containing protease inhibitors (5 µg/ml
leupeptin, 1.5 mM benzamidine, 200 U/ml
aprotinin, 2 µg/ml pepstatin A, 10 µg/ml PMSF, and 1 mM EDTA), and then the homogenates were mixed
with SDS-PAGE stop solution. Cultured hippocampal cells were scraped together directly in stop solution. Samples were analyzed by 8% SDS-PAGE and Western blotting with ECL detection (Amersham Pharmacia Biotech, Piscataway, NJ) using cGK I antiserum diluted 1:3000 or
affinity-purified cGK II antibody (Markert et al., 1995) diluted 1:1000. In separate experiments, the immunolabeling specificity of the
cGK antibodies was demonstrated by antibody preabsorption with
recombinant cGK I or cGK II purified from Sf9 cells.
Reverse transcription-PCR. Total RNA from cultured
hippocampal neurons was isolated using Trizol Reagent from Life
Technologies (Grand Island, NY), and reverse transcription (RT)
was performed using a kit from Life Technologies with oligo-dT
priming. For cDNA amplification, the primers used for human cGK I were
5'-GGAGACGTGGGGTCACT-GGTG-3' (sense, position 503-523 nt) and
5'-AAAGAAGGTGTCCCC-TCTTGC-3' (antisense, position 860-880 nt),
and for rat cGK II were 5'-CGAGGGTAGACTGGAGGTGTT-3' (sense, position
674-694 nt) and 5'-AATGGGGAGGTTGAGGAGAAT-3' (antisense, position
1376-1396 nt). The cDNA was submitted to 35 PCR cycles (94°C, 40 sec; 56°C, 40 sec; and 72°C, 1 min), followed by final elongation
at 72°C for 10 min. Samples of PCR products were analyzed by
electrophoresis on 1.5% agarose gels and staining with ethidium bromide.
Kinase activity. The cultured cells were washed with PBS and
incubated in serum-free medium with or without 250 µM 8-pCPT-cGMP for 30 min at 37°C. The
reaction was terminated by addition of SDS-PAGE stop solution, and
samples were analyzed by Western blotting as described above. The
nitrocellulose blot was divided into two pieces, and the high molecular
weight protein range was incubated with cGK I antibody, whereas the
lower range was incubated with monoclonal 16C2 antibody (Smolenski et
al., 1998), which recognizes the endogenous cGK substrate
vasodilator-stimulated phosphoprotein (VASP) phosphorylated on Ser-239
as a 46 kDa protein (VASP-P). VASP-P was identified by comparison with
a standard prepared from a lysate of human platelets that had been
incubated with sodium nitroprusside to cause phosphorylation of VASP.
Immunocytochemistry. Hippocampal cultures on glass
coverslips were fixed in 4% paraformaldehyde in PBS, pH 7.4, at 4°C
for 1 hr, washed three times with PBS, permeabilized in 0.1% Triton X-100 for 10 min at room temperature, and washed three more times in
PBS. The free aldehydes were then quenched with 50 mM ammonium chloride in PBS for 15 min at room
temperature, and nonspecific antibody binding was blocked with 10%
normal goat serum in PBS for 30 min at room temperature. The cultures
were then incubated with the two primary antibodies, rabbit anti-cGK I
(Markert et al., 1995) or preimmune serum diluted 1:300 and either
mouse anti-microtubule-associated protein 2 (MAP2) (Sigma, 5 µg/ml) or mouse monoclonal anti-synaptophysin (5 µg/ml; Boehringer
Mannheim, Indianapolis, IN) at 4°C overnight. The cultures were
washed three times in PBS and then incubated with the secondary
antibodies, goat anti-rabbit antibody conjugated with Cy3 (Jackson
ImmunoResearch, West Grove, PA) diluted 1:100 and goat anti-mouse
antibody conjugated with Cy5 (Jackson ImmunoResearch) diluted 1:100 in
10% goat serum in PBS at room temperature for 1 hr. The cultures were
then washed four to five times with PBS, mounted in Fluoromount-G, and
examined with a Bio-Rad (Hercules, CA) MRC 1000 laser confocal
scanning system coupled to a Zeiss (Oberkochen, Germany) Axiovert 100 inverted microscope with a 100×, 1.3 numerical aperture oil immersion
objective. The cultures were excited using the 568 and 647 lines of a
krypton-argon laser to image Cy3 and Cy5. Kalman averages of four
scans were collected for each image.
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RESULTS |
We first replicated the previous finding (Arancio et al., 1995,
1996) that three trains of tetanic stimulation (50 Hz, 2 sec) of the
presynaptic neuron during brief perfusion with
Mg2+-free saline reliably produced rapid
and long-lasting potentiation of the EPSC at synapses between
individual hippocampal neurons in culture (Fig.
1). In control experiments with no
tetanic stimulation, there was a slight rundown of the baseline EPSC
attributable to the whole-cell ruptured patch recording. To test
the role of cGK in long-lasting potentiation, we injected a peptide
inhibitor of cGK (cGKi) into either the presynaptic or postsynaptic
neuron. This novel peptide Gly-Arg-Thr-Gly-Arg-Arg-Asn-(D-Ala)lle-NH2 blocks the phospho-acceptor binding site of the kinase and is the most
specific cGK inhibitory pseudosubstrate currently available (Lev-Ram et
al., 1997). After injection of cGKi (100 µM;
Ki of 14.8 µM,
Lev-Ram et al., 1997) into the postsynaptic neuron tetanic stimulation
still induced long-lasting potentiation, although the potentiation was
somewhat reduced compared with normal. In contrast, injection of cGKi
into the presynaptic neuron completely blocked potentiation. In control
experiments with no tetanic stimulation, injection of cGKi into either
the presynaptic or postsynaptic neuron did not affect the stability of
the baseline EPSC. A two-way ANOVA with one repeated measure (test
time) revealed that the six training procedures in Figure 1C
produced significantly different amounts of potentiation
(F(5,88) = 8.72; p < 0.01). Subsequent pairwise comparisons showed that tetanic stimulation
with postsynaptic cGKi produced significantly less potentiation than
tetanic stimulation alone (p < 0.05), but that
either produced significantly greater potentiation than the other four
training procedures (including test alone control and tetanic
stimulation with presynaptic cGKi; p < 0.01 in each
case), which were not significantly different from each other. These
results suggest that presynaptic cGK is necessary for the potentiation
and that postsynaptic cGK may also play a role.
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Figure 1.
Presynaptic injection of cGKi blocks
potentiation by tetanic stimulation. A, Experimental
arrangement. B1, Example of
potentiation by tetanic stimulation of the presynaptic neuron after
injection of cGKi into the postsynaptic neuron. EPSCs were produced in
the postsynaptic neuron by step depolarization sufficient to elicit an
inward current in the presynaptic neuron once every 10 sec. The current
in the presynaptic neuron has had leakage subtracted. Both recordings
are a.c.-coupled. Sample traces are shown before
(Pre) and 25 min after tetanic stimulation of the
presynaptic neuron (three 50 Hz, 2 sec trains of depolarizations at 20 sec intervals) during brief perfusion with Mg2+-free
solution. Four successive traces are superimposed at each time period.
The dashed line shows the average Pre value.
B2, Example of block of potentiation
by injection of cGKi into the presynaptic neuron. C,
Average potentiation produced by tetanic stimulation (a; filled
inverted triangles) and slight rundown of the EPSC in
test-alone controls (b; open inverted triangles).
Injection of cGKi into the postsynaptic neuron reduced but did not
block potentiation by tetanic stimulation (c; filled
triangles), whereas injection of cGKi into the presynaptic
neuron completely blocked the potentiation (d; filled
circles). Injection of cGKi alone into either the postsynaptic
neuron (e; open triangles) or the presynaptic neuron (f;
open circles) had no effect on the baseline EPSC. EPSC
amplitude has been normalized to the average value during the 10 min
before training (% of Pre) in each experiment.
Average Pre values in picoamperes were as follows: (a) 137 ± 33, n = 21; (b) 157 ± 86, n = 15; (c) 123 ± 39, n = 22; (d) 110 ± 43, n = 11; (e) 325 ± 191, n = 12; and (f) 178 ± 108, n = 13; not
significantly different by a one-way ANOVA. Tetanic stimulation
(3 arrows) occurred at time 0. The horizontal
bar shows the time during which the bath solution was briefly
changed to one with 0 Mg2+. The inhibitor was
present throughout the experiment. Each point represents
the average of 20 successive trials, and the numbers at
25 min indicate the n at that point. Some experiments
were terminated earlier if the electrode seal was lost or the input
resistance changed in either the presynaptic or postsynaptic cell. The
points indicate the means, the error bars indicate SEM,
and asterisks indicate a significant difference from
both the Pre level (dashed line) and the nontetanized
controls.
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To test whether the presynaptic injection procedure itself might have
interfered with the ability of the cell to undergo potentiation, we injected a peptide containing the same amino acids as cGKi with
their sequence scrambled (ScGKi). Unlike cGKi, injection of ScGKi (100 µM) into the presynaptic neuron did not prevent long-lasting potentiation by tetanic stimulation (Fig.
2). Injection of cGKi might also have
blocked potentiation by inhibiting cAK, although cGKi is 70 times more
potent an inhibitor of cGK than of cAK (Lev-Ram et al., 1997).
Therefore, as an additional control, we injected a specific peptide
inhibitor of cAK [cAKi or PKI-(6-22)-amide, 20 µM;
Ki of 1.7 nM]
(Glass et al., 1989) into either the presynaptic or postsynaptic neuron
and found that it also did not block long-lasting potentiation.
Presynaptic cAKi may have produced some reduction of the potentiation
but it was less effective than cGKi, although cAKi was injected at a
much higher concentration relative to its Ki. The ScGKi and cAKi
injections also did not have effects on the baseline EPSC. A two-way
ANOVA revealed that the six training procedures in Figure 2C
produced significantly different amounts of potentiation
(F(5,69) = 9.76; p < 0.01).
Subsequent pairwise comparisons showed that the three groups with
tetanic stimulation were not significantly different from each other
and that each produced significantly greater potentiation than the
three groups without tetanic stimulation (p < 0.05 in each case), which were also not significantly different from
each other. These results suggest that the block of long-lasting
potentiation by injection of cGKi is not attributable to nonspecific
effects of the injection and also that cGKi did not block the
potentiation by inhibiting cAK.
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Figure 2.
Injection of ScGKi or cAKi does not block
potentiation. A, Experimental arrangement.
B1, Example of potentiation by tetanic
stimulation after injection of cAKi into the postsynaptic neuron.
B2, Example of potentiation by tetanic
stimulation after injection of cAKi into the presynaptic neuron.
C, Average potentiation by tetanic stimulation after
injection of ScGKi into the presynaptic neuron (a; filled
inverted triangles). Tetanic stimulation also still produced
potentiation after injection of cAKi into either the postsynaptic
neuron (b; filled triangles) or the presynaptic neuron
(c; filled circles). Injection of ScGKi alone into the
presynaptic neuron (d; open inverted triangles) or
injection of cAKi alone into either the postsynaptic neuron (e;
open triangles) or the presynaptic neuron (f;
open circles) did not have an effect on EPSC amplitude.
Average Pre values in picoamperes were as follows: (a) 116 ± 46, n = 8; (b) 60 ± 24, n = 13; (c) 90 ± 24, n = 19; (d) 83 ± 30, n = 13; (e) 130 ± 44, n = 7; and (f) 136 ± 49, n = 15; not
significantly different by a one-way ANOVA.
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The results of the inhibitor experiments suggest that presynaptic cGK
plays an important role in long-lasting potentiation and that
postsynaptic cGK may also be involved. However, they do not say which
type of cGK is involved. Two genes have been identified in vertebrates
that encode for cGK type I (which is soluble) and cGK type II (which is
membrane-associated) (Wernet et al., 1989; Uhler, 1993; Jarchau et al.,
1994; Orstavik et al., 1997). cGK type I mRNA has been detected in
several types of neurons, including pyramidal neurons in the CA1 and
CA3 regions of hippocampus (Kingston et al., 1996; Kleppisch et al.,
1999), and cGK type II is also present in a number of brain areas,
including hippocampus (El Husseini et al., 1995; Kleppisch et al.,
1999). We tested for the presence of the two types of cGK protein by
Western blotting. Both cultured hippocampal cells and microdissected
hippocampus contained an endogenous protein that migrated like cGK type
I (Fig.
3A1), and
this signal was blocked by preabsorption of the antibody with
recombinant cGK type I, demonstrating its specificity. In contrast, cGK
type II was detected in microdissected hippocampus but not (or only
very faintly) in cultured hippocampal cells (Fig. 3A2). Similarly, cGK type I but not cGK
type II mRNA was detected in cultured hippocampal cells by RT-PCR (Fig.
3B). As additional evidence for the presence of cGK as well
as its functional activity, treatment of intact cultured hippocampal
cells with 8-pCPT-cGMP caused an increase in phosphorylation of an
endogenous substrate, VASP, at a residue (Ser-239) that is
preferentially phosphorylated by cGKs (Smolenski et al., 1998) (Fig.
3C). cGK type I immunolabeling in the same samples was
constant, indicating that loading of the  and + 8-pCPT-cGMP
lanes was equal and that the increased VASP-P signal in the + lanes was
attributable to increased kinase activity.
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Figure 3.
Cultured hippocampal neurons contain cGK type I. A, Western blot demonstration of endogenous cGK type I
in cultured hippocampal cells. Standards of recombinant cGK I and cGK
II (76 and 86 kDa, respectively) purified from Sf9 cells were used for
identifying cGKs in samples (25 µg of protein) from hippocampal
cultures or microdissected hippocampus. Both cultured hippocampal cells
and microdissected hippocampus contained a protein that migrated like
cGK I (A1). The cGK I signals were
blocked by antibody (Ab) preabsorption, indicating that
they are specific. Microdissected hippocampus also contained a protein
that migrated like cGK II, but cultured hippocampal cells did not
(A2). B, In agreement
with the Western blot analysis, the RT-PCR technique detected cGK I but
not cGK II mRNA in samples from cultured hippocampal cells. RT-PCR
products obtained using oligonucleotide primers specific for cGK I and
cGK II were analyzed using 1.5% agarose gels and ethidium bromide
staining. DNA molecular weight standards (Marker) and
the PCR product for cGK I (378 kb; arrow) are indicated.
A cGK II product of expected size, 725 kb, was not detected.
C, cGMP-dependent phosphorylation of an endogenous
substrate protein, VASP. Hippocampal cultures were incubated in
serum-free media with or without 8-pCPT-cGMP, and samples (30 µg of protein) were analyzed by Western blotting using a monoclonal
antibody that recognized VASP phosphorylated on Ser-239 (which is
preferentially phosphorylated by cGKs) as a 46 kDa protein. VASP-P was
identified by comparison with a standard prepared from human platelets
(left). cGK I was also assayed in the same samples, as
described for A1. D,
Immunocytochemical localization of cGK type I in cultured hippocampal
neurons. Cultured hippocampal cells showed positive immunoreactivity
for cGK type I (green) compared with control
cells treated with preimmune serum. The same cells that displayed
positive labeling for cGK type I also showed positive labeling for MAP2
(red), a specific neuronal marker located in cell bodies
and dendrites, confirming that the cGK I-labeled cells were neurons
(left). They also showed positive labeling for
synaptophysin (red), a presynaptic vesicle-associated
protein, indicating that the localization of cGK type I includes
presynaptic terminals (middle). Double-labeled
structures appear yellow or orange. Scale
bar, 10 µm.
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These results demonstrate that cGK type I is present and functional in
the cell cultures. However, they do not show that cGK type I is present
in neurons (as opposed to glia) and more specifically in presynaptic
terminals, as would be expected for a presynaptic function. To test
these possibilities, we used immunocytochemical techniques with a
primary antibody against cGK type I. As illustrated in Figure
3D, cultured hippocampal neurons showed positive
immunoreactivity compared with control neurons treated with the
preimmune serum. The immunoreactivity appeared to be fairly evenly
distributed throughout the neuron except for the nucleus, as would be
expected from the cytoplasmic localization of cGK type I. The same
cells that showed positive immunoreactivity for cGK type I also
double-labeled with an antibody against MAP2, a specific neuronal
marker located in cell bodies and dendrites, confirming that the cells
were neurons. To test whether cGK type I is also present in presynaptic
terminals, we double-labeled with an antibody against synaptophysin, a
vesicle-associated protein that is commonly used as a presynaptic
marker. Most of the structures that labeled for synaptophysin also
double-labeled for cGK type I (Fig. 3D, yellow or
orange), indicating that the localization of endogenous cGK
type I includes presynaptic terminals.
We next examined whether injection of cGK type I is able to produce
long-lasting potentiation. The protein was introduced into either the
presynaptic or postsynaptic neuron by means of a fast internal
perfusion method (Arancio et al., 1995). Because we have found
previously that presynaptic injection of cGMP or presynaptic release of
caged NO produce potentiation only if they are paired with weak tetanic
stimulation of the presynaptic neuron (Arancio et al., 1995, 1996), we
injected cGK type I either by itself or paired with a weak tetanus (50 Hz, 0.5 sec). The cultures were bathed in saline containing normal
Mg2+ and the NMDA antagonist APV (50 µM) throughout the experiments to ensure that the weak
tetanus by itself did not produce potentiation (Fig.
4). Injection of the isozyme of cGK
type I (0.5 µM) into the presynaptic neuron, paired with
weak tetanic stimulation of that neuron, produced rapid and
long-lasting potentiation of the EPSC. It was not necessary to coinject
cGMP with the cGK type I, suggesting either that the kinase has some
cGMP-independent activity or that basal levels of endogenous cGMP can
produce sufficient stimulation of the kinase if it is present in
excess. In contrast, injection of cGK type I into the postsynaptic
neuron paired with weak tetanus produced no potentiation. Injection of
cGK type I into either neuron also did not affect the baseline EPSC. A
two-way ANOVA revealed that the five training procedures in Figure
4C produced significantly different amounts of potentiation
(F(4,48) = 4.67; p < 0.01). Subsequent pairwise comparisons showed that presynaptic
injection of cGK type I paired with weak tetanus produced significantly
greater potentiation than each of the other training procedures
(p < 0.01 in each case), which were not
significantly different from each other. These results indicate that
presynaptic cGK, in conjunction with weak tetanic stimulation, is
sufficient as well as necessary for long-lasting potentiation in
cultured hippocampal neurons.
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Figure 4.
Presynaptic injection of cGK type I produces
activity-dependent long-lasting potentiation. A,
Experimental arrangement. B1, Example
of long-lasting potentiation produced by injection of the isozyme
of cGK type I into the presynaptic neuron paired with weak tetanic
stimulation (50 Hz, 0.5 sec) of that neuron in the presence of 50 µM APV. B2, Example
of lack of potentiation by injection of cGK type I into the
postsynaptic neuron paired with weak tetanic stimulation.
C, Average potentiation by presynaptic injection of cGK
type I paired with weak tetanic stimulation (a; filled
circles). The weak tetanus (arrow) occurred at
time 0. The horizontal bar shows the time during which
cGK type I was injected into the neuron. The cultures were perfused
with APV throughout the experiment. There was no potentiation after
either postsynaptic injection of cGK type I paired with weak tetanic
stimulation (b; filled triangles) or weak tetanic
stimulation alone (c; filled inverted triangles).
Injection of cGK type I alone into the presynaptic neuron (d;
open circles) or the postsynaptic neuron (e; open
triangles) did not have an affect on EPSC amplitude. Average
Pre values in picoamperes were as follows: (a) 43 ± 9, n = 15; (b) 173 ± 44, n = 11; (c) 22 ± 4, n = 8; (d) 153 ± 53, n = 11; and (e) 178 ± 92, n = 8.
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DISCUSSION |
cGKs are cGMP-binding proteins that function as mediators of
intracellular signaling in many cell types (Lohmann et al., 1997), but
their function in the nervous system is generally poorly understood. Previous research has suggested that cGMP and cGK play a role in LTP in
the CA1 region of hippocampal slices, although the results have been
somewhat mixed. A number of studies have found that LTP is blocked by
inhibitors of either guanylyl cyclase or cGK (Zhuo et al.,
1994b; Blitzer et al., 1995; Boulton et al., 1995; Son et al.,
1998; Lu et al., 1999), but other studies have found no effect of those
inhibitors (Schuman et al., 1994; Gage et al., 1997). Similarly,
several studies have found that cGMP analogs can produce
activity-dependent long-lasting potentiation (Haley et al., 1992; Zhuo
et al., 1994b; Son et al., 1998; Lu et al., 1999), whereas other
studies have failed to replicate that effect (Schuman et al., 1994;
Selig et al., 1996). One possible explanation for the differing results
in these different studies is that LTP in hippocampal slices has
multiple components involving several different mechanisms (only some
of which involve NO, cGMP, and cGK) and that the different mechanisms
make larger or smaller contributions depending on the experimental
procedures (Son et al., 1998; Zhuo et al., 1998; Lu et al., 1999). For
example, Son et al. (1998) found that activity-dependent potentiation
by cGMP analogs is optimal when a relatively large, rapid rise in cGMP is combined with relatively brief, high-frequency activity. A smaller
or slower rise in cGMP or presynaptic activity can actually lead to
long-lasting depression (Zhuo et al., 1994a; Gage et al., 1997)
and, at intermediate levels, potentiation and depression may cancel
out. These findings might help to explain the negative results from
studies in which cGMP analogs were applied for relatively long times
(Schuman et al., 1994; Selig et al., 1996).
Recently, Kleppisch et al. (1999) took a different approach to
examining the role of cGK in LTP in hippocampal slices by testing mice
with either single or double knock-outs of cGK type I and cGK type II
and found that LTP was normal in those mice. They therefore concluded
that cGK is not involved in LTP, although it is possible that there was
compensation by other pathways in the knock-out animals. Furthermore,
Kleppisch et al. (1999) also found no effect of a guanylyl cyclase
inhibitor or of cGMP analogs on LTP in wild-type animals. Thus, it
appears likely that they performed their experiments under conditions
in which the cGMP-cGK pathway makes a minimal contribution, so that
knock-out of cGK would be expected to have little effect.
In light of the more complicated results in hippocampal slices, it is
somewhat surprising that the NO-cGMP-cGK pathway appears to make a
very large, if not dominant, contribution to long-lasting potentiation
in culture. The potentiation in culture can be almost completely
blocked by cGKi (Fig. 1) or pharmacological inhibitors of NO synthase,
guanylyl cyclase, or cGK (Arancio et al., 1995, 1996). Conversely,
exogenous cGK (Fig. 4), NO, or cGMP (Arancio et al., 1995, 1996) can
produce activity-dependent potentiation comparable with that produced
by tetanic stimulation. In these studies, the exogenous substances were
applied as rapidly as possible just before the presynaptic activity,
which may have optimized their effects. In addition, the cells in
culture probably are not fully mature so that the potentiation may
engage end-stage developmental processes that involve NO, cGMP, and cGK
(Hindley et al., 1997; Leamey and Sur, 1999; Van Wagenen and Rehder,
1999) in addition to mature plasticity mechanisms.
One question that has been difficult to address in hippocampal slices
is whether various molecules such as NO, cGMP, and cGK exert their
effects in the presynaptic or postsynaptic neuron. Blitzer et al.
(1995) found that the cGK inhibitor Rp-8-Br-cGMPS blocked LTP in slices
when the inhibitor was applied to the bath but not when it was injected
into the postsynaptic neuron, suggesting that cGK may act in the
presynaptic neuron. However, testing this idea by injecting substances
presynaptically has not been possible in hippocampal slices. This
limitation, among others, has motivated research on hippocampal neurons
in dissociated cell culture, in which both sides of the synapse are
accessible to substances injected into the presynaptic or postsynaptic
cell body (Alder et al., 1992; Popov and Poo, 1992; Arancio et al.,
1996). Our results with injections of cGKi or cGK type I into the
presynaptic neuron are consistent with previous results showing that
presynaptic NO or cGMP can produce activity-dependent long-lasting
potentiation in culture (Arancio et al., 1995, 1996) and suggest that
they act predominantly by stimulating presynaptic cGK during the
induction of the potentiation.
In addition to these presynaptic effects, we found that intracellular
injection of cGKi into the postsynaptic neuron reduced but did not
completely block potentiation, suggesting a possible role for
postsynaptic cGK as well. Lu et al. (1999) have also provided evidence
for a postsynaptic role of cGK in late-phase LTP in hippocampal slices.
However, a postsynaptic effect of cGKi would appear to be inconsistent
with negative results from postsynaptic injections of cGK type I (Fig.
4), NO, or cGMP (Arancio et al., 1995, 1996). Because in those
experiments the intracellular effects of cGK type I, NO, or cGMP were
all tested with the NMDA antagonist APV in the bath, one possible
explanation is that the postsynaptic but not the presynaptic actions of
cGK may require coincident NMDA receptor activation (Son et al.,
1998).
Presynaptic cGK type I, like cGMP or NO (Arancio et al., 1995, 1996)
produced potentiation only when it was paired with weak tetanic
stimulation. Because this potentiation was not blocked by APV, the cGK
did not simply act to make the weak tetanus stronger and thereby
enhance Ca2+ current through postsynaptic
NMDA receptor channels. Previous studies have also shown that cGMP
analogs do not alter the postsynaptic current during the tetanus either
in culture (Arancio et al., 1995) or in slices (Son et al., 1998). One
other possibility is that cGK may act synergistically with
Ca2+ that enters the presynaptic terminal
during the weak tetanus, perhaps by converging on a common molecular
target. Consistent with that possibility, Antonova et al. (2000)
recently found that the NO-cGMP-cGK pathway contributes to an
increase in the number of synaptophysin- and synapsin-immunoreactive
presynaptic terminals during long-lasting potentiation in hippocampal
cell culture. Those results provide independent evidence that cGK acts
presynaptically and indicate that it in some way affects
vesicle-associated proteins. It will now be interesting to examine how
activation of cGK contributes to changes in presynaptic
immunoreactivity and synaptic transmission during long-lasting potentiation.
| |
FOOTNOTES |
Received June 26, 2000; revised Oct. 17, 2000; accepted Oct. 18, 2000.
The research was supported by National Institutes of Health Grants
MH50733 and GM45989 and grants from the Whitehall Foundation, the
Deutsche Forschungsgemeinschaft, and the Howard Hughes Medical Institute. We thank A. MacDermott, E. R. Kandel, and S. Siegelbaum for their comments, H. Ayers, A. Krawetz, and M. Pellan for typing this
manuscript, and C. Lam for help with the figures.
Correspondence should be addressed to Dr. Robert D. Hawkins, Center for
Neurobiology and Behavior, Columbia University, 1051 Riverside Drive,
New York, NY 10032. E-mail: rhawkins{at}pi.cpmc.columbia.edu.
| |
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ABSTRACT
INTRODUCTION
