 |
 Previous Article | Next Article 
The Journal of Neuroscience, January 1, 1998, 18(1):458-466
Involvement of Presynaptic and Postsynaptic Mechanisms in a
Cellular Analog of Classical Conditioning at Aplysia
Sensory-Motor Neuron Synapses in Isolated Cell Culture
Jian-Xin
Bao1,
Eric R.
Kandel1, 2, 3, and
Robert D.
Hawkins1, 2
1 Center for Neurobiology and Behavior, College of
Physicians and Surgeons, Columbia University, 2 New York
State Psychiatric Institute, and 3 Howard Hughes Medical
Institute, New York, New York 10032
 |
ABSTRACT |
Temporal pairing of presynaptic activity and serotonin produces
enhanced facilitation at Aplysia sensory-motor neuron
synapses (pairing-specific facilitation), which may contribute to
classical conditioning of the gill and siphon withdrawal reflex. This
cellular analog of conditioning is thought to involve
Ca2+ priming of the cAMP pathway in the sensory
neurons. Consistent with that idea, we have found that pairing-specific
facilitation by serotonin is greatly reduced by presynaptic injection
of a slow Ca2+ chelator or a specific inhibitor of
cAMP-dependent protein kinase and is accompanied by a transient
increase in the frequency but by no change in the amplitude of
spontaneous, miniature EPSPs. However, like post-tetanic potentiation
(PTP) and long-term potentiation (LTP) at these synapses,
pairing-specific facilitation is also greatly reduced by postsynaptic
injection of a rapid Ca2+ chelator or by
postsynaptic hyperpolarization during training, although postsynaptic
hyperpolarization has no effect on the increase in frequency or on the
amplitude of spontaneous EPSPs. These results suggest that
pairing-specific facilitation by serotonin involves Hebbian
postsynaptic as well as non-Hebbian presynaptic components that
interact in some way, perhaps via retrograde signaling, to specifically
enhance evoked, synchronized release of transmitter.
Key words:
Aplysia; pairing-specific facilitation; serotonin; sensory neuron; motor neuron; cell culture; calcium; cAMP-dependent protein kinase
| |
INTRODUCTION |
The gill and siphon withdrawal
reflex of Aplysia undergoes classical conditioning when a
weak tactile stimulus to the siphon [the conditioned stimulus (CS)]
occurs just before a noxious stimulus to the tail [the unconditioned
stimulus (US)] (Carew et al., 1981 , 1983). In a neural analog of the
conditioning, presynaptic facilitation of siphon sensory neurons by
tail shock is enhanced or amplified when spike activity in the sensory
neurons just precedes the tail shock (Hawkins et al., 1983). Because
this analog occurs at synapses in the circuit for the reflex with the
same temporal parameters as behavioral conditioning, it is thought to
contribute to the conditioning (Hawkins et al., 1983; Clark et al.,
1994). A similar analog of conditioning occurs at synapses of the tail
sensory neurons (Walters and Byrne, 1983). In addition, plasticity also occurs at other sites during conditioning (Colebrook and Lukowiak, 1988; Lukowiak and Colebrook, 1988).
The analog of conditioning in the ganglion has been suggested to be
caused by an enhancement of the same mechanisms that contribute to
sensitization of the reflex (Hawkins et al., 1983, 1993). Tail stimulation excites interneurons that release several modulatory transmitters including serotonin (5-HT), which produces presynaptic facilitation of the siphon sensory neurons. Serotonin acts in part by
stimulating adenylate cyclase to produce cAMP, which acts via
cAMP-dependent protein kinase to produce closure of
K+ channels, spike broadening, increased
Ca2+ influx, and increased transmitter release.
Serotonin can also produce facilitation via protein kinase C and a
second process that may involve transmitter mobilization (Byrne and
Kandel, 1996). Activity-dependent enhancement of the facilitation is
thought to be caused in part by priming of the adenylate cyclase by
Ca2+ that enters the sensory neurons during the
spike activity (Abrams, 1985). Consistent with this hypothesis,
serotonin can substitute for tail shock in a neural analog of
conditioning at synapses between individual sensory and motor neurons
in isolated cell culture. Moreover, this pairing-specific facilitation
by serotonin is accompanied by enhancement of both excitability and
spike broadening in the sensory neurons, and quantal analysis indicates
that it is expressed presynaptically as enhancement of transmitter
release (Eliot et al., 1994a).
However, in addition to causing firing of facilitator interneurons,
tail stimulation also produces firing of the motor neurons, so that
activity-dependent facilitation by tail stimulation could be
attributable in part to Hebbian potentiation caused by coincident firing of the sensory and motor neurons. Aplysia
sensory-motor neuron synapses use L-glutamate or a similar
transmitter that activates NMDA-like receptors (Dale and Kandel, 1993;
Trudeau and Castellucci, 1993), and therefore these synapses might have similarities with mammalian synapses that undergo NMDA-dependent Hebbian long-term potentiation (LTP) (Hawkins et al., 1993). Carew et
al. (1984) failed to find any evidence of Hebbian potentiation at these
synapses by depolarizing or hyperpolarizing the motor neurons. More
recently, however, several studies have provided evidence that these
synapses undergo Hebbian LTP that is dependent on postsynaptic
depolarization and increased Ca2+ (Cui and Walters,
1994; Lin and Glanzman, 1994a,b; Murphy and Glanzman, 1996). A possible
explanation for these different results is that the more recent studies
were able to control conditions in the synaptic region more
effectively. In addition, Bao et al. (1997) and Cui and Walters (1994)
have found that post-tetanic potentiation (PTP), which has been thought
to be entirely presynaptic, also involves similar postsynaptic
mechanisms at these synapses. We have therefore examined the possible
contribution of postsynaptic as well as presynaptic mechanisms to
pairing-specific facilitation by serotonin at Aplysia
sensory-motor neuron synapses in cell culture.
Parts of this paper have been published previously in abstract form
(Bao and Hawkins, 1995, 1996).
| |
MATERIALS AND METHODS |
Cell culture. The techniques for making
Aplysia sensory-motor neuron cocultures have been described
previously (Schacher and Proshansky, 1983; Schacher, 1985). In most
experiments, a single identified L7 gill motor neuron was isolated from
the abdominal ganglion of a juvenile (1-4 gm) Aplysia
(Howard Hughes Medical Institute Mariculture Facility, Miami, FL) and
cocultured with two mechanosensory neurons isolated from the pleural
ganglion of an adult (70-100 gm) animal. In other experiments, an LFS
siphon motor neuron was isolated from an adult animal. Results with L7 and LFS motor neurons were similar and have been pooled. The two sensory neurons were placed on opposite sides of the motor neuron near
the initial segment of its main axon and 50-100 µm apart (see Fig.
1A) to minimize the formation of electrical coupling between them. The cells were plated in culture dishes coated with 0.5 mg/ml poly-L-lysine and were incubated at 18°C for 4-6
d. The culture medium consisted of 50% filtered Aplysia
hemolymph and 50% L-15 medium supplemented with 34.6 mM
D-glucose and the following salts (in mM):
NaCl, 260; CaCl2, 10.1; KCl, 4.6;
MgSO4, 25; MgCl2, 28; and
NaHCO3, 2.3. Additionally, glutamine (1 mM), penicillin (50 U/ml), and streptomycin (50 µg/ml)
were also included in the culture medium. All chemicals were from Sigma
(St. Louis, MO) unless otherwise indicated.
Electrophysiology. The motor neuron was impaled with a
microelectrode (6-15 M ) filled with 2.5 M KCl for
recording of EPSPs. The electrical signals were amplified with an
Axoclamp 2B amplifier (Axon Instruments, Foster City, CA) and recorded
on a four-channel tape recorder. A conventional bridge balance circuit
was used to inject current through the recording electrode. Because it is not possible to produce PTP while the sensory neuron is impaled with
an intracellular electrode (Eliot et al., 1994b), sensory neurons were
stimulated with brief (0.1 msec) depolarizing pulses delivered through
an extracellular electrode pressed against the soma. The motor neuron
was hyperpolarized 30 mV (1.2-3.1 nA; on average, 1.79 ± 0.06 nA) below the resting membrane potential throughout the experiment to
minimize spike initiation and to allow accurate measurement of EPSPs.
Under these conditions, the minimum amplitude of an EPSP that would
initiate a spike was ~50 mV, which was approximately three times the
average amplitude of the initial EPSPs. After 30 min of rest (or, in
some experiments, 30 min after the start of presynaptic or postsynaptic
injections), EPSPs were evoked from each sensory neuron at ~5 min
intervals for 40 min. On each trial, one sensory neuron was stimulated
1 min after the other. The peak amplitude and initial slope of the EPSPs were measured automatically with an interface to a microcomputer and commercially available software (Hilal Associates, Englewood, NJ).
For PTP experiments, a tetanus (20 Hz for 2 sec) was applied to one of
the sensory cells 10 min after the first EPSP in the series (see Fig.
1B), and the stimulus intensity was increased 20-30% above that used to evoke the previous EPSP, which was
sufficient to produce one-for-one EPSPs during the tetanus; the other
sensory cell served as a test-alone control. For experiments on paired training, a single puff of 5-HT (50 µM) was applied in
the vicinity of the cells ~0.5 sec (0.48 ± 0.05 sec) after the
start of a tetanus, which was also delivered at "10 min." The 5-HT
did not affect the number of EPSPs produced during the tetanus. For
experiments on unpaired training, the tetanus was given at 9 min, 1 min
before 5-HT application. At the beginning of each experiment, one of the two sensory neurons was assigned randomly to receive paired or
unpaired training; the other sensory neuron served as a 5-HT-alone control. Puffs of 5-HT solution were applied from a low resistance electrode positioned upstream of the cells and connected to a Pico-Injector (pressure, 0.3-0.5 psi; 800 msec in duration) (Medical Systems, Greenvale, NY). The concentration of 5-HT reaching the cells
should have been approximately the same as that in the pipette during
the puff. Fast green (0.2%), which alone did not affect synaptic
transmission, was included in the 5-HT solution to check the delivery
and location of the puff and to estimate the time of washout. Quick
(<60 sec) washout of 5-HT was achieved by continuous perfusion of the
culture dish at a rate of ~0.5 ml/min with 50% supplemented L-15
medium and 50% artificial seawater (in mM: NaCl, 460; KCl,
11; CaCl2, 10; MgCl2, 27; and
MgSO4, 27). All experiments were performed at room
temperature (20-23°C) on cultures 4-6 d after plating, by which
time sensory-motor neuron synapses become stable (Bank and Schacher,
1992; Zhu et al., 1994).
Intracellular injections. For pressure injections, the tip
of the injection electrode was beveled to have a resistance of 3-6
M. The electrode was connected to a Pico-Injector (Medical Systems),
and pulses of pressure (800 msec in duration; 0.3-1.4 psi) were
delivered at 2 sec intervals for 10-60 sec. The injection electrode
was then withdrawn from the cell, and stimulation of the sensory neuron
with an extracellular electrode was begun after 30 min of rest. EGTA
was first dissolved in KOH, and the pH was adjusted to 7.5 with HCl.
Fast green (0.2%) was usually included in the EGTA solution or the
control vehicle solution to visually ensure successful injection. The
peptide inhibitor of protein kinase A (fragment 6-22 amide,
Thr-Tyr-Ala-Asp-Phe-Ile-Ala-Ser-Gly-Arg-Thr-Gly-Arg-Arg-Asn-Ala-Ile-NH2) was dissolved in 0.86 M KCl, and lissamine-rhodamine B
(1.7%) (Gurr Diagnostic, High Wycombe, Bucks, England) was included in the solution to monitor the injection. Injections were stopped when the
cell body turned pink, and diffusion into the processes was checked
with a fluorescence microscope at the end of the experiments. By these
criteria, the injections of the protein kinase A inhibitor into the
sensory and motor neurons were comparable. In some experiments, both
rhodamine and Lucifer yellow were separately injected into the sensory
and motor neurons to check for dye coupling between the two cells. For
injection of BAPTA (Molecular Probes, Eugene, OR) into the motor
neuron, the neuron was impaled with a microelectrode filled with BAPTA
dissolved in 2.5 mM KCl, and BAPTA was injected either by
iontophoresis (0.5-1 nA; 500 msec; 1 Hz) or diffusion. Similar results
were obtained after 20-30 min of iontophoretic application or
diffusion. For hyperpolarization of the motor neuron, it was injected
with 4 nA of current from ~20 sec before to 20 sec after the tetanus
or 5-HT application. This current injection produced ~50-100 mV of
additional hyperpolarization below the level at which the neuron was
held throughout the rest of the experiment, as measured in the soma.
The hyperpolarization could have been substantially less at the
synaptic region, however.
Spontaneous miniature EPSPs. For these experiments, only a
single sensory neuron was cocultured with a motor neuron. Recording of
spontaneous miniature EPSPs (mEPSPs) was made at high gain, filtered at
300 Hz ( 3 dB), and AC-coupled, whereas evoked EPSPs were recorded at
low gain and DC-coupled. Signals were digitized off-line using a
personal computer-based Fetchex program (part of the Pclamp package;
Axon Instruments) and were analyzed using an Axobasic program. mEPSPs
were identified visually based on the following criteria: (1) a rise
time of 3-20 msec, (2) a half decay time of at least 5 msec, and (3) a
minimum amplitude of 50 µV, which was usually ~25% greater than
the peak-to-peak noise level (Eliot et al., 1994a,b). The frequency and
the peak amplitude of mEPSPs were then automatically determined by the
computer.
Sensory neuron excitability. Isolated sensory neurons in
culture were used for these experiments. Excitability was measured by
counting the number of spikes produced by a 500 msec intracellular depolarizing current pulse before and during perfusion with 5-HT (20 µM for 2 min). The current intensity was adjusted to
produce one spike before exposure to 5-HT.
Statistics. Most of the data in the text and figures are
expressed as mean ± SEM (n represents the number of
cultures) and normalized to the first test EPSP (30 min after the
impalement), except where otherwise indicated. Data were analyzed
statistically by t tests or two-way ANOVAs with one repeated
measure (time), and then comparisons were made at each time point by
one-way ANOVAs followed by Fisher's protected least significant
difference (PLSD) tests.
| |
RESULTS |
We examined EPSPs produced in an Aplysia motor neuron
by stimulating individual cocultured sensory neurons. In agreement with Eliot et al. (1994a,b), in test-alone controls, the evoked EPSPs underwent homosynaptic depression, i.e., declined over time even when
the stimulation interval was as long as 5 min (Fig.
1Ba). A single brief
tetanic stimulation (20 Hz for 2 sec) of the sensory neuron induced PTP
that lasted 15-20 min (Fig. 1Bb). Puffing 5-HT (50 µM) into the vicinity of cells produced facilitation that lasted 5-10 min (Fig. 1Bc). Temporal (0.5 sec
forward interstimulus interval) pairing of tetanic stimulation with a
single puff of 5-HT produced larger facilitation that lasted >30 min
(pairing-specific facilitation) (Fig. 1Bd). Tetanus
and 5-HT given 1 min apart (unpaired training) produced only
short-lasting facilitation (Fig. 1Be). On average,
the facilitation by paired training was significantly larger than the
facilitation by unpaired training (for comparison, see Fig. 4),
replicating the results of Eliot et al. (1994a). As an additional
control, pairing the tetanus with a similar amount of vehicle solution
did not produce enhanced facilitation but only a PTP-like potentiation
(117.9 ± 7.9% 1 min after the pairing; n = 3).
View larger version (58K):
[in this window]
[in a new window]
|
Figure 1.
The experimental preparation and representative
recordings. A, Micrograph of an Aplysia
gill motor neuron (L7) isolated from the
abdominal ganglion of a juvenile animal and cocultured with two sensory
neurons (SN) from the pleural ganglion of an
adult animal. Scale bar, 100 µm. B, Original
recordings from five representative experiments, showing
(a) homosynaptic depression of EPSPs caused by
test-alone stimulation of a sensory neuron at ~5 min intervals, (b) PTP caused by a tetanus
(arrow) to the sensory neuron applied at 10 min,
(c) short-term facilitation induced by a single
puff of 5-HT (open triangle) applied at 10 min,
(d) facilitation induced by paired training (5-HT
applied ~0.5 sec after the start of a tetanus given at 10 min), and
(e) facilitation induced by unpaired training
(5-HT applied 1 min after a tetanus given at 9 min). The recordings in
c and d were taken from an experiment in
which one sensory neuron received both tetanus and 5-HT and the other only 5-HT. The double EPSPs in e may be caused by double
spikes in the sensory neuron.
|
|
Role of presynaptic Ca2+
Pairing-specific facilitation by serotonin is thought to be
attributable in part to priming of adenylate cyclase by
Ca2+ that enters the sensory neurons during the
spike activity (Abrams, 1985; Eliot et al., 1994a). To investigate the
contribution of presynaptic Ca2+ to pairing-specific
facilitation more directly, we pressure injected the sensory neuron
with EGTA, a Ca2+ chelator with slow kinetics that
buffers residual Ca2+ without affecting transmitter
release (Adler et al., 1991). Presynaptic EGTA reduces potentiation by
tetanic stimulation (PTP) at these synapses (Bao et al., 1997).
Presynaptic EGTA (50 mM in the electrode) also
substantially reduced pairing-specific facilitation to a level
comparable with that produced by 5-HT alone (Fig.
2) but did not significantly affect
baseline EPSPs (Fig. 2, control) or the area under the summed EPSPs
during the pairing (t10 = 1.25, not
significant). Overall, there were significant differences between the
four groups in Figure 2 [F(3,32) = 15.63 for
treatment; p = 0.0001; F(24,256) = 9.25 for treatment × time; p = 0.0001], and
there were significant differences between the paired group (paired/control) and the paired group with EGTA injection (paired/EGTA) at each test from 5 to 30 min after training.
View larger version (25K):
[in this window]
[in a new window]
|
Figure 2.
Presynaptic EGTA reduces pairing-specific
facilitation. Paired training is indicated by an arrow
(tetanus) and a large open triangle (5-HT). In both
control (open circles) and paired/control (open
squares) groups, sensory neurons received injection of vehicle solution. The 5-HT-alone (small open triangles) data
were obtained from the second sensory neurons in the cultures that did
not receive any injection but only 5-HT puffs. For this and subsequent
figures, *p < 0.05, **p < 0.01, and ***p < 0.001 versus control;
#p < 0.05, ##p < 0.01, and
###p < 0.001 versus paired/control by Fisher's PLSD tests. The average amplitudes of EPSPs on trial one, 30 min after
impalement, were 12.7 ± 2.1 mV (control), 22.5 ± 6.5 mV (paired/control), 12.2 ± 2.5 mV (paired/EGTA), and 19.1 ± 3.5 mV (5-HT), not significantly different from each other
[F(3,35) = 1.39; p = 0.2625].
|
|
In agreement with Clark et al. (1994), we found that there was an
increase in the initial slope of evoked EPSPs that paralleled the
increase in amplitude of EPSPs after paired training
[F(8,55) = 5.25; p < 0.001;
p < 0.05 at each test from 1 to 15 min after training], suggesting that pairing-specific facilitation may involve some mechanism in addition to spike-broadening in the sensory neurons
(Hochner et al., 1986). Furthermore, presynaptic injection of EGTA
reduced the increase in slope of the EPSPs in parallel with its effect
on their amplitude (p < 0.05 at each test from 5 to 20 min after training; n = 4). These results
suggest that both spike broadening and any additional mechanism of
pairing-specific facilitation require an increase in presynaptic
Ca2+.
Role of presynaptic cAMP-dependent protein kinase
Several lines of evidence suggest that pairing-specific
facilitation involves cAMP-mediated processes in the sensory neuron (Abrams, 1985; Hawkins et al., 1993; Eliot et al., 1994a). To test
directly whether presynaptic cAMP-dependent protein kinase (PKA) is
involved in pairing-specific facilitation, we pressure injected a
specific peptide inhibitor of PKA (PKAI6-22) (Cheng et
al., 1985) into the sensory neuron. Presynaptic injection of
PKAI6-22 (500 µM in the electrode) reduced
pairing-specific facilitation to a level comparable with PTP, whereas
sensory neurons receiving vehicle injection exhibited normal
pairing-specific facilitation (Fig.
3A). PKAI6-22
injected into the sensory neuron had no effect on basal synaptic
transmission (Fig. 3A, control). Overall, there were
significant differences between the seven groups in Figure
3A-C [F(6,51) = 21.12 for
treatment; p = 0.0001; F(48,408) = 9.83 for treatment × time; p = 0.0001], and
there were significant differences between the paired/control group and
the paired/PKAI(pre) group at each test after training.
View larger version (38K):
[in this window]
[in a new window]
|
Figure 3.
Presynaptic but not postsynaptic injection of a
protein kinase A inhibitor (PKAI6-22) reduces
pairing-specific facilitation. A, Presynaptic
PKAI6-22 [PKAI(pre)] significantly
reduced the facilitation induced by paired training indicated by an
arrow (tetanus) and a large open triangle
(5-HT). For both control and paired/control groups, sensory neurons
received injection of vehicle solution. PTP by tetanus alone is plotted
here for comparison (same data plotted as PTP/ctr in B).
B, Presynaptic PKAI6-22 had no effect on
PTP. The control group is replotted for comparison. C,
Presynaptic PKAI6-22 reduced 5-HT-induced facilitation; #p < 0.05 versus 5-HT. The average amplitudes of
EPSPs on trial one, 30 min after impalement, in A-C
were 14.6 ± 2.6 mV (control), 15.8 ± 4.9 mV
(paired/control), 24.0 ± 3.3 mV [paired/PKAI(pre)], 12.3 ± 2.7 mV (PTP/control), 18.2 ± 5.2 mV [PTP/PKAI(pre)],
20.4 ± 2.8 mV (5-HT/control), and 19.9 ± 6.9 mV
[5-HT/PKAI(pre)], not significantly different
[F(6,51) = 2.15; p = 0.0638]. D, Postsynaptic injection of
PKAI6-22 [PKAI(post)] did not
significantly affect pairing- or 5-HT-induced facilitation. For
control, paired/control, and 5-HT/control groups, the motor neurons
were injected with vehicle solution. EPSPs 30 min after impalement had
amplitudes of 15.4 ± 2.5 mV (control), 12.8 ± 1.3 mV
(paired/control), 19.2 ± 4.6 mV [paired/PKAI(post)], 21.4 ± 4.7 mV (5-HT/control) and 17.4 ± 3.9 mV [5-HT/PKAI(post)],
not significantly different [F(4,32) = 0.83; p = 0.5146].
|
|
PKAI6-22 injected into the sensory neuron had essentially
no effect on PTP (Fig. 3B). However, injection of
PKAI6-22 into the sensory neuron did reduce short-term
facilitation by serotonin (Fig. 3C). There were significant
differences between the 5-HT/control and the 5-HT/PKAI(pre) groups 1 and 10 min after training. In separate experiments,
PKAI6-22 injected into a sensory neuron also significantly
reduced the increase in sensory neuron excitability by 5-HT (vehicle,
15 ± 2 spikes; n = 3; PKAI6-22, 3.2 ± 0.9 spikes; n = 5;
t6 = 6.22; p = 0.0008). These
effects of 5-HT are thought to be mediated at least in part by the
cAMP-PKA pathway, confirming that PKAI6-22 inhibited the
activity of PKA in the sensory neuron. Synaptic facilitation by 5-HT at depressed synapses is also thought to be mediated in part by protein kinase C (Byrne and Kandel, 1996), which could account for the remaining facilitation 1 min after 5-HT (Fig. 3C).
By contrast, injection of PKAI6-22 into the
postsynaptic cell did not have any appreciable effect on
pairing-specific facilitation or 5-HT-induced short-term facilitation
(Fig. 3D), suggesting that the induction of pairing-specific
facilitation probably does not require cAMP-PKA in the postsynaptic
neuron. Overall, there were significant differences between the five
groups in Figure 3D [F(4,30) = 12.91 for treatment; p = 0.0001;
F(32,240) = 8.96 for treatment × time;
p = 0.0001], but there were no significant differences
between the paired/control and paired/PKAI(post) groups or the
5-HT/control and 5-HT/PKAI(post) groups.
Taken together, the results of these experiments and the EGTA injection
experiments suggest that 5-HT-induced facilitation (cAMP-PKA pathway)
and tetanus-induced potentiation (Ca2+-? pathway)
are independent presynaptic processes and that both cAMP and
Ca2+ must be elevated in the presynaptic neuron to
produce pairing-specific facilitation. Moreover, the fact that
explicitly unpaired training with the tetanus and 5-HT applied 1 min
apart did not induce long-lasting facilitation indicates that
presynaptic Ca2+ and cAMP act synergistically and
are not simply additive.
Role of postsynaptic Ca2+ and
membrane potential
Both LTP and PTP at Aplysia sensory-motor neuron
synapses in cell culture are dependent on postsynaptic depolarization
and Ca2+ elevation (Lin and Glanzman, 1994a,b; Bao
et al., 1997). We therefore examined the possible involvement of these
postsynaptic events in pairing-specific facilitation. Postsynaptic
injection of BAPTA (200 mM in the electrode), a
Ca2+ chelator with fast kinetics (Adler et al.,
1991), greatly reduced facilitation by paired training but did not
significantly affect that by unpaired training or by 5-HT (Fig.
4A-C). Overall, there were significant differences between the seven groups in Figure 4A-C [F(6,60) = 14.76 for
treatment; p = 0.0001; F(48,480) = 8.32 for treatment × time; p = 0.0001].
Replicating the results of Eliot et al. (1994a), there were significant
differences between paired and unpaired training at each test from 5 to
30 min after training (p < 0.01 in each case).
There were also significant differences between the paired and
paired/BAPTA groups at each test after training, but there were no
significant differences between the unpaired and unpaired/BAPTA or
between the 5-HT and 5-HT/BAPTA groups.
View larger version (32K):
[in this window]
[in a new window]
|
Figure 4.
Postsynaptic BAPTA or postsynaptic
hyperpolarization during training reduce pairing-specific facilitation
but not facilitation by unpaired training or by 5-HT.
A-C, Effect of postsynaptic BAPTA on facilitation
induced by paired presentation of a tetanus (arrow) and
5-HT (large open triangle) (A), by
unpaired training (B), and by 5-HT
(C). The 5-HT alone and 5-HT/BAPTA results are
from the second sensory neuron in the same culture that did not receive tetanic stimulation and are pooled from both paired and unpaired training groups. Average EPSP amplitudes on trial one, 30 min after
impalement, were 14.3 ± 1.5 mV (control), 18.2 ± 2.0 mV (paired), 14.9 ± 1.5 mV (paired/BAPTA), 13.3 ± 1.5 mV
(unpaired), 21.5 ± 3.3 mV (unpaired/BAPTA), 20.1 ± 1.9 mV
(5-HT), and 20.7 ± 2.9 mV (5-HT/BAPTA), not significantly
different [F(6,66) = 1.68;
p = 0.1417]. D-F, Effect of
postsynaptic hyperpolarization (HPP) on facilitation by
paired training (D), by unpaired training (E), and by 5-HT (F). The
average amplitudes of EPSPs 30 min after impalement were 14.1 ± 1.9 mV (control), 16.0 ± 3.0 mV (paired), 15.9 ± 2.6 mV
(paired/HPP), 11.7 ± 2.4 mV (unpaired), 18.7 ± 2.3 mV
(unpaired/HPP), 18.5 ± 2.8 mV (5-HT), and 19.6 ± 3.1 mV
(5-HT/HPP), not significantly different
[F(6,48) = 0.96; p = 0.4628].
|
|
Similarly, strong hyperpolarization (4 nA) of the motor neuron during
training significantly reduced facilitation produced by pairing but
left unaffected facilitation by unpaired training or by 5-HT (Fig.
4D-F). On average, the motor neuron was
hyperpolarized longer during unpaired training than during
paired training, but there was overlap, and the results did not
correlate with duration of hyperpolarization. Overall, there were
significant differences between the seven groups in Figure
4D-F [F(6,42) = 11.49 for
treatment; p = 0.0001; F(48,336) = 8.00 for treatment × time; p = 0.0001]. Again,
there were significant differences between paired and unpaired training
at each test from 1 to 30 min after training (p < 0.01 in each case). There were also significant differences between the paired and paired/HPP groups at each test after training, but there
were no significant differences between the unpaired and unpaired/HPP
or between the 5-HT and 5-HT/HPP groups.
Previous control experiments indicate that postsynaptic BAPTA or
hyperpolarization does not affect the presynaptic neuron through gap
junctions or electrical coupling (Bao et al., 1997). As additional
evidence, we found that either rhodamine or Lucifer yellow injected
into the sensory or motor neuron did not appear in the uninjected cell
(data not shown), suggesting that there is also minimal dye coupling
between the sensory and motor neurons. These results thus suggest that
the induction of pairing-specific facilitation involves depolarization
and an increase in Ca2+ in the postsynaptic
neuron.
Postsynaptic hyperpolarization during paired training does not
affect spontaneous miniature EPSPs
To try to determine which aspect of synaptic transmission is
affected by these postsynaptic manipulations, we analyzed the effect of
postsynaptic hyperpolarization on both evoked EPSPs and spontaneous
mEPSPs during paired training. Consistent with the results of Eliot et
al. (1994a), paired training of the sensory neuron that induced a
long-lasting facilitation of evoked EPSPs also produced a transient
increase in the frequency of mEPSPs (Fig.
5A,B)
but did not significantly increase the amplitude of mEPSPs (Fig.
5C,E). Although there were too few spontaneous
mEPSPs to detect small changes in their amplitude in any individual
experiment (Fig. 5C), the results were very consistent
between experiments, so that fairly small changes could have been
detected in the average results (Fig. 5E). Whereas paired
training produced a significant increase in the amplitude of evoked
EPSPs (t4 = 8.52; p < 0.001), there was no significant change in the amplitude of spontaneous mEPSPs
during the same time period. These results suggest that pairing-specific facilitation involves a presynaptic increase in
transmitter release.
View larger version (24K):
[in this window]
[in a new window]
|
Figure 5.
Effects of paired training and postsynaptic
hyperpolarization during paired training on spontaneous release.
A, B, HPP reduced pairing-induced facilitation of evoked EPSPs (eEPSPs)
(A) but not the pairing-induced increase in the
frequency of spontaneous mEPSPs
(B). Paired training is indicated by a combined
arrow (tetanus) and open triangle (5-HT).
A, EPSPs on trial one, 30 min after impalement, had
amplitudes of 22.2 ± 3.9 mV (paired) and 27.0 ± 3.9 mV
(paired/HPP), not significantly different
(t8 = 0.87; p = 0.4089).
B, The average frequency of mEPSPs 30 min after
impalement was 0.059 ± 0.013 and 0.048 ± 0.005 Hz for
paired and paired/HPP groups, respectively, not significantly different
(t8 = 0.76; p = 0.4683).
C, Amplitude distribution of mEPSPs at a representative synapse before (2-9 min) and after (10-15 min) paired training. Paired training did not increase the amplitude of mEPSPs. In this experiment, the mean amplitudes of mEPSPs before and after the training
were 88.1 ± 7.6 µV (n = 8) and 84.8 ± 6.4 µV (n = 19), respectively, not significantly
different (t25 = 0.30; p = 0.7658). D, Postsynaptic hyperpolarization during
paired training also did not affect mEPSP amplitude. In this
experiment, the mean amplitudes of mEPSPs before and after the training
were 95.9 ± 8.1 µV (n = 13) and 105.4 ± 9.1 µV (n = 8), respectively, not
significantly different (t19 = 0.76;
p = 0.4552). E, Summary of effects
of paired training and postsynaptic hyperpolarization during pairing
(paired/HPP) on amplitudes of eEPSPs and mEPSPs. For eEPSPs,
"pre" and "post" were defined as the average of EPSP amplitudes
at 0 and 5 min and at 11 and 15 min, respectively; for mEPSPs,
"pre" and "post" were defined as the average amplitude of
mEPSPs during 2-9 min and 10-15 min, respectively;
**p < 0.01 and ***p < 0.001 versus pre; ##p < 0.01 versus paired by
t tests.
|
|
Replicating the results shown in Figure 4D, strong
hyperpolarization (4 nA) of the postsynaptic motor neuron during paired training reduced pairing-induced facilitation of evoked EPSPs (Fig.
5A). Overall, there was a significant difference between paired training and paired training during hyperpolarization
(paired/HPP) [F(1,8) = 10.98 for treatment;
p = 0.0106; F(8,64) = 12.12 for treatment × time; p = 0.0001]. However,
hyperpolarization during paired training did not significantly affect
the increase in frequency of mEPSPs (Fig. 5B) or the
amplitude of mEPSPs (Fig. 5D,E),
although it did significantly reduce the increase in amplitude of
evoked EPSPs during the same time period (t8 = 4.92; p < 0.0012). These results suggest that
postsynaptic hyperpolarization during paired training affects some
aspect of transmitter release that is specific to evoked release.
| |
DISCUSSION |
Mechanisms contributing to pairing-specific facilitation
by serotonin
Our results support the hypothesis that pairing-specific
facilitation at Aplysia sensory-motor neuron synapses
involves Ca2+ priming of the cAMP pathway in the
presynaptic neurons (Abrams, 1985; Hawkins et al., 1993; Eliot et al.,
1994a). In agreement with Eliot et al. (1994a), we found that paired
training produced no change in the amplitude of spontaneous mEPSPs,
suggesting that pairing-specific facilitation is expressed
presynaptically as an increase in transmitter release (Fig. 5).
Moreover, presynaptic injection of the Ca2+ chelator
EGTA (Fig. 2) or an inhibitor of PKA (Fig. 3A) reduced pairing-specific facilitation to approximately the level of
facilitation by 5-HT alone or PTP alone, respectively. However,
postsynaptic injection of the Ca2+ chelator BAPTA or
postsynaptic hyperpolarization during training also greatly reduced
facilitation by paired training but had little effect on facilitation
by unpaired training (Fig. 4), suggesting that postsynaptic mechanisms
also contribute to pairing-specific facilitation. Long-term (24 hr)
pairing-specific facilitation produced by four training trials (but not
one training trial) is similarly reduced by postsynaptic
hyperpolarization during training (Schacher et al., 1997).
Because most of the enhancement of facilitation by pairing was
eliminated by either presynaptic (Figs. 2, 3A) or
postsynaptic (Fig. 4) manipulations, these two types of mechanisms are
evidently not additive but interact in some way. One possibility is
that Ca2+ elevation in the postsynaptic neuron leads
to formation of a retrograde messenger that then interacts with
Ca2+ or cAMP in the presynaptic neuron to enhance
some aspect of transmitter release. Eliot et al. (1994a) found that
paired training produced a transient increase in the frequency of
spontaneous mEPSPs, but that unpaired training also produced a similar
increase. Consistent with that result, we found that pairing-specific
facilitation was accompanied by an increase in the frequency of
spontaneous mEPSPs, but that increase did not last as long as the
facilitation of evoked EPSPs (Fig.
5A,B). Moreover, postsynaptic
hyperpolarization reduced the facilitation of evoked EPSPs but did not
significantly affect the frequency or the amplitude of spontaneous
mEPSPs (Fig. 5). These results therefore suggest that the putative
retrograde messenger does not affect spontaneous release but rather
acts to specifically enhance evoked, synchronous release. Similar
mechanisms are thought to contribute to PTP at these synapses (Bao et
al., 1997), suggesting that pairing-specific facilitation and PTP may affect the same or similar aspects of transmitter release.
Mechanisms contributing to learning
Both pairing-specific facilitation by serotonin and Hebbian LTP
could contribute to activity-dependent facilitation by tail stimulation, which in turn is thought to contribute to classical conditioning of the gill and siphon withdrawal reflex (Hawkins et al.,
1983; Clark et al., 1994) and to site-specific sensitization of the
tail withdrawal reflex (Walters, 1987; Cui and Walters, 1995). Murphy
and Glanzman (1996) recently reported that activity-dependent facilitation by tail stimulation is blocked by postsynaptic injection of BAPTA, and they suggested that the facilitation may be caused primarily by Hebbian LTP. Surprisingly, our results indicate that pairing-specific facilitation by 5-HT is also blocked by postsynaptic BAPTA (Fig. 4A), so that BAPTA injection does not
discriminate between these two mechanisms, and their relative
contributions to activity-dependent facilitation by tail stimulation
remain unknown. Moreover, Abrams and Galun (1995) found that
activity-dependent facilitation by tail stimulation, like
pairing-specific facilitation by serotonin (Fig. 3A), is
also blocked by presynaptic injection of an inhibitor of cAMP-dependent
protein kinase. These results indicate that Hebbian postsynaptic and
activity-dependent presynaptic mechanisms may both be required for
activity-dependent facilitation by tail stimulation, and therefore
attempting to determine their relative contributions may not be the
correct way of thinking about the problem. Rather, as our data suggest,
Aplysia sensory-motor neuron synapses may have a single
hybrid mechanism with Hebbian postsynaptic and activity-dependent
presynaptic components. Such a hybrid mechanism might combine the
advantages of activity-dependent presynaptic facilitation by a
modulatory transmitter, which is well suited for learning which stimuli
occur just before a motivationally significant event, and Hebbian
potentiation, which is synapse-specific and therefore might provide a
mechanism for the response specificity of classical conditioning
(Hawkins et al., 1989). A hybrid mechanism might also account for the
temporal specificity of conditioning (Clark et al., 1994), whereas a
purely Hebbian mechanism would not (Lin and Glanzman, 1997).
Recent data suggest that long-term potentiation in the CA1 region of
hippocampus, which has been thought to be purely Hebbian, also involves
a similar (but not identical) hybrid combination of Hebbian
postsynaptic and activity-dependent presynaptic components (Hawkins et
al., 1993; Zhuo et al., 1993; Arancio et al., 1996). These results
support the idea that such hybrid mechanisms may be more widespread.
Thus, the elementary mechanisms of synaptic plasticity that have been
identified previously may form an alphabet of basic components that are
combined in various ways in the nervous system, presumably permitting a
greater range of functional synaptic modifications (Hawkins and Kandel,
1984).
| |
FOOTNOTES |
Received May 23, 1997; revised Sept. 11, 1997; accepted Oct. 9, 1997.
This work was supported by National Institute of Mental Health Grant
MH26212 and a grant from the Howard Hughes Medical Institute. A
long-term fellowship from the Human Frontier Science Program Organization to J.-X.B. is gratefully acknowledged. We thank H. Ayers
and I. Trumpet for typing this manuscript.
Correspondence should be addressed to Dr. Robert D. Hawkins, Center for
Neurobiology and Behavior, Columbia University, 722 West 168th Street,
New York, NY 10032.
| |
REFERENCES |
-
Abrams TW
(1985)
Activity-dependent presynaptic facilitation: an associative mechanism in Aplysia.
Cell Mol Neurobiol
5:123-145[Web of Science][Medline].
-
Abrams TW,
Galun JE
(1995)
Role of adenylyl cyclase and cAMP in associative facilitation at sensory neuron synapses in Aplysia.
Soc Neurosci Abstr
21:1023.
-
Adler EM,
Augustine GJ,
Duffy SN,
Charlton MP
(1991)
Alien intracellular calcium chelators attenuate neurotransmitter release at squid giant synapse.
J Neurosci
11:1496-1507[Abstract].
-
Arancio O,
Kiebler M,
Lee LJ,
Lev-Ram V,
Tsien RY,
Kandel ER,
Hawkins RD
(1996)
Nitric oxide acts directly in the presynaptic neuron to produce long-term potentiation in cultured hippocampal neurons.
Cell
87:1025-1035[Web of Science][Medline].
-
Bank M,
Schacher S
(1992)
Segregation of presynaptic inputs on an identified target neuron in vitro: structural remodeling visualized over time.
J Neurosci
12:2960-2972[Abstract].
-
Bao J-X,
Hawkins RD
(1995)
A postsynaptic contribution to posttetanic potentiation (PTP) and pairing-specific facilitation at Aplysia sensory-motor synapses in cell culture.
Soc Neurosci Abstr
21:1024.
-
Bao J-X,
Hawkins RD
(1996)
Posttetanic potentiation and activity-dependent facilitation at Aplysia cultured sensory-motor neuron synapses involve both pre- and postsynaptic mechanisms.
Soc Neurosci Abstr
22:695.
-
Bao J-X,
Kandel ER,
Hawkins RD
(1997)
Involvement of pre- and postsynaptic mechanisms in posttetanic potentiation at Aplysia synapses.
Science
275:969-973[Abstract/Free Full Text].
-
Byrne JH,
Kandel ER
(1996)
Presynaptic facilitation revisited: state and time dependence.
J Neurosci
16:425-435[Abstract/Free Full Text].
-
Carew TJ,
Walters ET,
Kandel ER
(1981)
Classical conditioning in a simple withdrawal reflex in Aplysia californica.
J Neurosci
1:1426-1437[Abstract].
-
Carew TJ,
Hawkins RD,
Kandel ER
(1983)
Differential classical conditioning of a defensive withdrawal reflex in Aplysia californica.
Science
219:397-400[Abstract/Free Full Text].
-
Carew TJ,
Hawkins RD,
Abrams TW,
Kandel ER
(1984)
A test of Hebb's postulate at identified synapses which mediate classical conditioning in Aplysia.
J Neurosci
4:1217-1224[Abstract].
-
Cheng HC,
van Pattern SM,
Smith AJ,
Walsh DA
(1985)
An active twenty-amino acid-residue peptide derived from the inhibitor protein of the cyclic AMP-dependent protein kinase.
Biochem J
231:655-661[Web of Science][Medline].
-
Clark GA,
Hawkins RD,
Kandel ER
(1994)
Activity-dependent enhancement of presynaptic facilitation provides a cellular mechanism for the temporal specificity of classical conditioning in Aplysia.
Learn Mem
1:243-257. [Abstract/Free Full Text]
-
Colebrook E,
Lukowiak K
(1988)
Learning by the Aplysia model system: lack of correlation between gill and gill motor neurone responses.
J Exp Biol
135:411-429[Web of Science].
-
Cui M,
Walters ET
(1994)
Homosynaptic LTP and PTP of sensorimotor synapses mediating the tail withdrawal reflex in Aplysia are reduced by postsynaptic hyperpolarization.
Soc Neurosci Abstr
20:1071.
-
Cui M,
Walters ET
(1995)
Long-term potentiation of Aplysia sensory neuron synapses after tail pinch: effects of postsynaptic hyperpolarization and BAPTA injection.
Soc Neurosci Abstr
21:1456.
-
Dale N,
Kandel ER
(1993)
L-Glutamate may be the fast excitatory transmitter of Aplysia sensory neurons.
Proc Natl Acad Sci USA
90:7163-7167[Abstract/Free Full Text].
-
Eliot LS,
Hawkins RD,
Kandel ER,
Schacher S
(1994a)
Pairing-specific, activity-dependent presynaptic facilitation of Aplysia sensory-motor neuron synapses in isolated cell culture.
J Neurosci
14:368-383[Abstract].
-
Eliot LS,
Kandel ER,
Hawkins RD
(1994b)
Modulation of spontaneous transmitter release during depression and posttetanic potentiation of Aplysia sensory-motor neuron synapses isolated in culture.
J Neurosci
14:3280-3292[Abstract].
-
Hawkins RD,
Kandel ER
(1984)
Is there a cell biological alphabet for simple forms of learning?
Psychol Rev
91:375-391[Web of Science][Medline].
-
Hawkins RD,
Abrams TW,
Carew TJ,
Kandel ER
(1983)
A cellular mechanism of classical conditioning in Aplysia: activity-dependent amplification of presynaptic facilitation.
Science
219:400-405[Abstract/Free Full Text].
-
Hawkins RD,
Lalevic N,
Clark GA,
Kandel ER
(1989)
Classical conditioning of the Aplysia siphon-withdrawal reflex exhibits response specificity.
Proc Natl Acad Sci USA
86:7620-7624[Abstract/Free Full Text].
-
Hawkins RD,
Kandel ER,
Siegelbaum SA
(1993)
Learning to modulate transmitter release: themes and variations in synaptic plasticity.
Annu Rev Neurosci
16:625-665[Web of Science][Medline].
-
Hochner B,
Klein M,
Schacher S,
Kandel ER
(1986)
Additional component in the cellular mechanism of presynaptic facilitation contributes to behavioral dishabituation in Aplysia.
Proc Natl Acad Sci USA
83:8794-8798[Abstract/Free Full Text].
-
Lin XY,
Glanzman DL
(1994a)
Long-term potentiation of Aplysia sensorimotor synapses in cell culture: regulation by postsynaptic voltage.
Proc R Soc Lond [Biol]
255:113-118[Medline].
-
Lin XY,
Glanzman DL
(1994b)
Hebbian induction of long-term potentiation of Aplysia sensorimotor synapses: partial requirement for activation of a NMDA-related receptor.
Proc R Soc Lond [Biol]
255:215-221[Medline].
-
Lin XY,
Glanzman DL
(1997)
Effect of interstimulus interval on pairing-induced LTP of Aplysia sensorimotor synapses in cell culture.
J Neurophysiol
77:667-674[Abstract/Free Full Text].
-
Lukowiak K,
Colebrook E
(1988)
Classical conditioning alters the efficacy of identified gill motor neurons in producing gill withdrawal movement in Aplysia.
J Exp Biol
140:273-285[Abstract/Free Full Text].
-
Murphy GG,
Glanzman DL
(1996)
Enhancement of sensorimotor connections by conditioning-related stimulation in Aplysia depends on postsynaptic Ca2+.
Proc Natl Acad Sci USA
93:9931-9936[Abstract/Free Full Text].
-
Schacher S
(1985)
Differential synapse formation and neurite outgrowth at two branches of the metacerebral cell of Aplysia in dissociated cell culture.
J Neurosci
5:2028-2034[Abstract].
-
Schacher S,
Proshansky E
(1983)
Neurite regeneration by Aplysia neurons in dissociated cell culture: modulation by Aplysia hemolymph and the presence of the initial axonal segment.
J Neurosci
3:2403-2413[Abstract].
-
Schacher S,
Wu F,
Sun ZY
(1997)
Pathway-specific synaptic plasticity: activity-dependent enhancement and suppression of long-term heterosynaptic facilitation at converging inputs on a single target.
J Neurosci
17:597-606[Abstract/Free Full Text].
-
Trudeau L-E,
Castellucci VF
(1993)
Excitatory amino acid neurotransmitter at sensory-motor and interneuronal synapses of Aplysia californica.
J Neurophysiol
70:1221-1230[Abstract/Free Full Text].
-
Walters ET
(1987)
Multiple sensory neuronal correlates of site-specific sensitization in Aplysia.
J Neurosci
7:408-417[Abstract].
-
Walters ET,
Byrne JH
(1983)
Associative conditioning of single sensory neurons suggests a cellular mechanism for learning.
Science
219:405-408[Abstract/Free Full Text].
-
Zhu H,
Wu F,
Schacher S
(1994)
Aplysia cell adhesion molecules and serotonin regulate sensory cell-motor cell interactions during early stages of synapse formation in vitro.
J Neurosci
14:6886-6900[Abstract].
-
Zhuo M,
Small SA,
Kandel ER,
Hawkins RD
(1993)
Nitric oxide and carbon monoxide produce activity-dependent long-term synaptic enhancement in the hippocampus.
Science
260:1946-1950[Abstract/Free Full Text].
Copyright © 1998 Society for Neuroscience 0270-6474/98/181458-09$05.00/0
This article has been cited by other articles:
|
|
|
|
 
I. Antonov, T. Ha, I. Antonova, L. L. Moroz, and R. D. Hawkins
Role of Nitric Oxide in Classical Conditioning of Siphon Withdrawal in Aplysia
J. Neurosci.,
October 10, 2007;
27(41):
10993 - 11002.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. Lovell and L. L. Moroz
The largest growth cones in the animal kingdom: an illustrated guide to the dynamics of Aplysia neuronal growth in cell culture
Integr. Comp. Biol.,
December 1, 2006;
46(6):
847 - 870.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. D. Hawkins, E. R. Kandel, and C. H. Bailey
Molecular Mechanisms of Memory Storage in Aplysia
Biol. Bull.,
June 1, 2006;
210(3):
174 - 191.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. J. Ha, A. B. Kohn, Y. V. Bobkova, and L. L. Moroz
Molecular Characterization of NMDA-Like Receptors in Aplysia and Lymnaea: Relevance to Memory Mechanisms
Biol. Bull.,
June 1, 2006;
210(3):
255 - 270.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. L. Glanzman
The Cellular Mechanisms of Learning in Aplysia: Of Blind Men and Elephants
Biol. Bull.,
June 1, 2006;
210(3):
271 - 279.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. Fino, J. Glowinski, and L. Venance
Bidirectional Activity-Dependent Plasticity at Corticostriatal Synapses
J. Neurosci.,
December 7, 2005;
25(49):
11279 - 11287.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Q. Li, A. C. Roberts, and D. L. Glanzman
Synaptic Facilitation and Behavioral Dishabituation in Aplysia: Dependence on Release of Ca2+ from Postsynaptic Intracellular Stores, Postsynaptic Exocytosis, and Modulation of Postsynaptic AMPA Receptor Efficacy
J. Neurosci.,
June 8, 2005;
25(23):
5623 - 5637.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Gais and J. Born
Declarative memory consolidation: Mechanisms acting during human sleep
Learn. Mem.,
November 1, 2004;
11(6):
679 - 685.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Molle, L. Marshall, S. Gais, and J. Born
Learning increases human electroencephalographic coherence during subsequent slow sleep oscillations
PNAS,
September 21, 2004;
101(38):
13963 - 13968.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
B. Brembs, D. A. Baxter, and J. H. Byrne
Extending In Vitro Conditioning in Aplysia to Analyze Operant and Classical Processes in the Same Preparation
Learn. Mem.,
July 1, 2004;
11(4):
412 - 420.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. A. Sutton, M. W. Bagnall, S. K. Sharma, J. Shobe, and T. J. Carew
Intermediate-Term Memory for Site-Specific Sensitization in Aplysia Is Maintained by Persistent Activation of Protein Kinase C
J. Neurosci.,
April 7, 2004;
24(14):
3600 - 3609.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. Mozzachiodi, H. A. Lechner, D. A. Baxter, and J. H. Byrne
In Vitro Analog of Classical Conditioning of Feeding Behavior in Aplysia
Learn. Mem.,
November 1, 2003;
10(6):
478 - 494.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. A. Phares, E. G. Antzoulatos, D. A. Baxter, and J. H. Byrne
Burst-Induced Synaptic Depression and Its Modulation Contribute to Information Transfer at Aplysia Sensorimotor Synapses: Empirical and Computational Analyses
J. Neurosci.,
September 10, 2003;
23(23):
8392 - 8401.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
I. Jin and R. D. Hawkins
Presynaptic and Postsynaptic Mechanisms of a Novel Form of Homosynaptic Potentiation at Aplysia Sensory-Motor Neuron Synapses
J. Neurosci.,
August 13, 2003;
23(19):
7288 - 7297.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. B. Renden and K. Broadie
Mutation and Activation of Galpha s Similarly Alters Pre- and Postsynaptic Mechanisms Modulating Neurotransmission
J Neurophysiol,
May 1, 2003;
89(5):
2620 - 2638.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. T. Tamse, Y. Xu, H. Song, L. Nie, and E. N. Yamoah
Protein Kinase A Mediates Voltage-Dependent Facilitation of Ca2+ Current in Presynaptic Hair Cells in Hermissenda crassicornis
J Neurophysiol,
March 1, 2003;
89(3):
1718 - 1726.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. A. Sutton and T. J. Carew
Behavioral, Cellular, and Molecular Analysis of Memory in Aplysia I: Intermediate-Term Memory
Integr. Comp. Biol.,
August 1, 2002;
42(4):
725 - 735.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. E. Fox and P. E. Lloyd
Mechanisms Involved in Persistent Facilitation of Neuromuscular Synapses in Aplysia
J Neurophysiol,
April 1, 2002;
87(4):
2018 - 2030.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. E. Fox and P. E. Lloyd
Evidence That Post-Tetanic Potentiation Is Mediated by Neuropeptide Release in Aplysia
J Neurophysiol,
December 1, 2001;
86(6):
2845 - 2855.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Thakker-Varia, J. Alder, R. A. Crozier, M. R. Plummer, and I. B. Black
Rab3A Is Required for Brain-Derived Neurotrophic Factor-Induced Synaptic Plasticity: Transcriptional Analysis at the Population and Single-Cell Levels
J. Neurosci.,
September 1, 2001;
21(17):
6782 - 6790.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
I. Antonov, I. Antonova, E. R. Kandel, and R. D. Hawkins
The Contribution of Activity-Dependent Synaptic Plasticity to Classical Conditioning in Aplysia
J. Neurosci.,
August 15, 2001;
21(16):
6413 - 6422.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. A Chitwood, Q. Li, and D. L Glanzman
Serotonin facilitates AMPA-type responses in isolated siphon motor neurons of Aplysia in culture
J. Physiol.,
July 15, 2001;
534(2):
501 - 510.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Keifer
In Vitro Eye-Blink Classical Conditioning Is NMDA Receptor Dependent and Involves Redistribution of AMPA Receptor Subunit GluR4
J. Neurosci.,
April 1, 2001;
21(7):
2434 - 2441.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. H. Bailey, M. Giustetto, H. Zhu, M. Chen, and E. R. Kandel
A novel function for serotonin-mediated short-term facilitation in Aplysia: Conversion of a transient, cell-wide homosynaptic Hebbian plasticity into a persistent, protein synthesis-independent synapse-specific enhancement
PNAS,
October 10, 2000;
97(21):
11581 - 11586.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. C. Gandhi and L. D. Matzel
Modulation of Presynaptic Action Potential Kinetics Underlies Synaptic Facilitation of Type B Photoreceptors after Associative Conditioning in Hermissenda
J. Neurosci.,
March 1, 2000;
20(5):
2022 - 2035.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. G. Murphy and D. L. Glanzman
Cellular Analog of Differential Classical Conditioning in Aplysia: Disruption by the NMDA Receptor Antagonist DL-2-Amino-5-Phosphonovalerate
J. Neurosci.,
December 1, 1999;
19(23):
10595 - 10602.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. Nargeot, D. A. Baxter, and J. H. Byrne
In Vitro Analog of Operant Conditioning in Aplysia. II. Modifications of the Functional Dynamics of an Identified Neuron Contribute to Motor Pattern Selection
J. Neurosci.,
March 15, 1999;
19(6):
2261 - 2272.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
O. A. Maksimova, N. I. Bravarenko, and P. M. Balaban
Two Modulatory Inputs Exert Reciprocal Reinforcing Effects on Synaptic Input of Premotor Interneurons for Withdrawal in Terrestrial Snails
Learn. Mem.,
March 1, 1999;
6(2):
168 - 176.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
K. Staras, G. Kemenes, and P. R. Benjamin
Cellular Traces of Behavioral Classical Conditioning Can Be Recorded at Several Specific Sites in a Simple Nervous System
J. Neurosci.,
January 1, 1999;
19(1):
347 - 357.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. D. Hawkins;, G. G. Murphy, and D. L. Glanzman;
Learning and the Sensorimotor Synapse in Aplysia
Science,
July 31, 1998;
281(5377):
619a - 619.
[Full Text]
|
|
|
|
|
|
|
J. Mauelshagen, C. M. Sherff, and T. J. Carew
Differential Induction of Long-Term Synaptic Facilitation by Spaced and Massed Applications of Serotonin at Sensory Neuron Synapses of Aplysia californica
Learn. Mem.,
July 1, 1998;
5(3):
246 - 256.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
T W Abrams, Y Yovell, C U Onyike, J E Cohen, and H E Jarrard
Analysis of sequence-dependent interactions between transient calcium and transmitter stimuli in activating adenylyl cyclase in Aplysia: possible contribution to CS--US sequence requirement during conditioning.
Learn. Mem.,
January 1, 1998;
4(6):
496 - 509.
[Abstract]
[PDF]
|
|
|
|
Top
Abstract
Introduction
