Presynaptic and Postsynaptic Mechanisms of a Novel Form of Homosynaptic Potentiation at Aplysia Sensory-Motor Neuron Synapses

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The Journal of Neuroscience, August 13, 2003, 23(19):7288-7297

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Presynaptic and Postsynaptic Mechanisms of a Novel Form of Homosynaptic Potentiation at Aplysia Sensory-Motor Neuron Synapses
Iksung Jin¹ and Robert D. Hawkins¹^,2
¹Center for Neurobiology and Behavior, Columbia University, and ²New York State Psychiatric Institute, New York, New York 10032

   Abstract

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Previous studies have shown that homosynaptic potentiation producedby rather mild tetanic stimulation (20 Hz, 2 sec) at Aplysia sensory-motor neuron synapses in isolated cell culture involvesboth presynaptic and postsynaptic Ca²⁺ (Bao et al., 1997).We have now investigated the sources of Ca²⁺ and some of its downstream targets. Although the potentiation lasts >30 min,it does not require Ca²⁺ influx through either NMDA receptor channels or L-type Ca²⁺ channels. Rather, the potentiationinvolves metabotropic receptors and intracellular Ca²⁺ releasefrom both postsynaptic IP₃-sensitive and presynaptic ryanodine-sensitivestores. In addition, it involves protein kinases, includingboth presynaptic and postsynaptic CamKII and probably MAP kinase.Finally, it does not require transsynaptic signaling by nitricoxide but it may involve AMPA receptor insertion. The potentiation,thus, shares components of the mechanisms of post-tetanic potentiation,NMDA- and mGluR-dependent long-term potentiation, and evenlong-term depression, but is not identical to any of them. These results are consistent with the more general idea that thereis a molecular alphabet of basic components that can be combinedin various ways to create novel as well as known types of plasticity.

Key words: Aplysia; potentiation; presynaptic; postsynaptic; Ca²⁺ stores; CamKII

   Introduction

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Synaptic plasticity occurs in a number of different types including homosynaptic and heterosynaptic, facilitatory and inhibitory,associative and nonassociative, and short term and long term.An important unresolved question has been whether these differenttypes of plasticity involve fundamentally different mechanisms,or whether they share an alphabet of basic mechanisms thatare combined in different ways. Aplysia sensory-motor neuron synapses in isolated cell culture provide a good preparationto address this question, because they exhibit all of the differenttypes of plasticity at one synapse (Rayport and Schacher, 1986; Montarolo et al., 1986, 1988; Schacher et al., 1990;Eliot et al., 1994a,b; Lin and Glanzman, 1994a,b; Bao etal., 1997, 1998; Schacher et al., 1997). In addition, theyhave a number of technical advantages for examining the mechanismsof plasticity. First, the neurons are identified individualswith known behavioral functions. Second, because there areno other neurons in the dish and they do not form autapses,one can unambiguously distinguish between homosynaptic andheterosynaptic effects and also know the source of spontaneousminiature EPSPs with certainty. Furthermore, because both sidesof the synapses are accessible to substances injected intothe cell bodies, one can manipulate presynaptic as well aspostsynaptic mechanisms.
For these reasons, we and others have used this preparationto study mechanisms of a variety of types of plasticity, includingpotentiation produced by rather mild (20 Hz, 2 sec) tetanizationof the presynaptic neuron. The behavioral relevance of thispotentiation is still unclear, but when the tetanus is pairedtemporally with serotonin, the two stimuli act synergisticallyto create an associative mechanism, activity-dependent presynapticfacilitation, that is thought to contribute to classical conditioningin Aplysia (Eliot et al., 1994a; Bao et al., 1998; Antonovet al., 2003). Thus, understanding mechanisms of the potentiationmay be important for understanding mechanisms of the more complexassociative effects.
Previous studies have revealed that the potentiation involvesaspects of the mechanisms of both post-tetanic potentiation(PTP) and long-term potentiation (LTP), including dependenceon both presynaptic and postsynaptic Ca²⁺ (Eliot et al., 1994b;Bao et al., 1997). We have now explored other molecules thatmight be involved, focusing on the sources of Ca²⁺ and someof its downstream targets. Our results indicate that the potentiationshares additional aspects of the mechanisms of PTP, both NMDA-dependentand mGluR-dependent LTP, and even long-term depression (LTD),but is not identical to any of them. It is, therefore, a novelform of plasticity that we now refer to simply as homosynapticpotentiation. These results are also consistent with the moregeneral idea that different types of plasticity do not involve fundamentally different mechanisms, but rather share an alphabetof basic mechanisms that can be combined in various ways toproduce novel as well as known types of plasticity.

   Materials and Methods

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Cell culture preparation. Aplysia cocultures (an L7 gill motor neuron and two pleural sensory neurons) were prepared as describedpreviously (Schacher, 1985; Bao et al., 1997) (Fig. 1 A).L7 motor neurons were isolated from juvenile (1-3 gm) animals,and pleural sensory neurons were isolated from adults (70 -120gm). All animals were purchased from the Howard Hughes MedicalInstitute Mariculture Facility (Miami, FL). The cell culturemedium consisted of 50% filtered hemolymph and 50% L-15 medium (Flow Laboratories, McLean, VA) supplemented with salts, D-glucose, glutamine, penicillin, and streptomycin (Bao et al., 1997).

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Figure 1. The experimental preparation and protocol. 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. One of the sensory neurons was stimulated with an extracellular electrode pressed against the cell body, and the evoked EPSP was recorded with a sharp intracellular electrode in the motor neuron. B, General protocol. After 30 min of rest or drug incubation, the EPSP was tested once every 5 min for 40 min. Tetanic stimulation (20 Hz, 2 sec) was delivered to the sensory neuron 1 min before the third test. C, Examples of the PSPs in a representative potentiation experiment and in a control experiment without tetanic stimulation. D, The average change in the PSP in all of the no-drug potentiation experiments (n = 119) and test-alone (homosynaptic depression) control experiments (n = 37) in this study. The data have been normalized to the value on the pretest in each experiment. The arrow indicates the time of tetanic stimulation, and the error bars indicate the SEM. There was no difference between experiments with and without DMSO, which have been pooled.

Electrophysiology. Four to six days after plating of the cells,a motor neuron was impaled with a microelectrode (10 -20 M ${Omega}$ )filled with 2.5 M KCl. Because it is not possible to producehomosynaptic potentiation while the sensory neuron is impaledwith an intracellular electrode (Eliot et al., 1994b), extracellularstimulation was used to stimulate one of the sensory neuronsand produce an EPSP. The other sensory neuron was not used in these experiments, although its presence is more physiologicaland may affect the results (Schacher et al., 1997). The motorneuron was hyperpolarized 30 mV below resting potential duringthe recording periods to allow measurement of the EPSP withoutaction potentials. After 30 min of rest or drug incubation,the EPSP was tested once every 5 min for 40 min. A tetanus(20 Hz for 2 sec) was applied to the sensory neuron 1 min beforethe third EPSP (Fig. 1 B). During the tetanus, the stimulationintensity was increased 20 -30% above that used to evoke theprevious PSP, which was sufficient to produce one-for-one EPSPs.In some experiments (test-alone or homosynaptic depressioncontrol), the tetanus was omitted. All experiments were performedat room temperature (20-23°C), and the culture dish wascontinuously perfused at a rate of 0.5 ml/min with 50% supplementedL-15 medium and 50% artificial seawater.
Drugs were included in the perfusion solution from the beginningof the 30 min rest period until the end of the experiment.The following drugs were used: APV and N-nitro-_L-arginine (Sigma,St. Louis, MO); nitrendipine, thapsigargin, 2-aminoethoxydiphenylborate(2APB), ryanodine, K252a, staurosporine, H7, KT5720, KT5823,lavendustin A, U0126, KN93, and calmidazolium (Calbiochem,La Jolla, CA); LY367385 and DNQX (Tocris Cookson, Ballwin,MO); oxymyoglobin and metmyoglobin (prepared as described in Lev-Ram et al., 1995). The concentrations of these drugs weregenerally 10 times the IC₅₀ reported by the manufacturer. Becausethat is based on mammalian data, we were also guided by previouslypublished Aplysia studies when possible. Nitrendiprine, thapsigargin,2APB, ryanodine, staurosporine, KT5720, KT5823, lavendustinA, U0126, KN93, and calmidazolium were prepared as stock solutions in DMSO and diluted to a final concentration of 0.1% DMSO. Inthose experiments, the control saline contained 0.1% DMSO.
Intracellular injections. Substances were injected by pressure from a 3-6 M ${Omega}$ electrode connected to a Pico-injector (MedicalSystems, Greenvale, NY). The injection solution consisted of0.5 M potassium acetate, 10 mM Tris-HCl to adjust the pH to7.5, 0.2% fast green to visualize the injection, and one ofthe following: 8-amino-cyclic ADP ribose (8NcADPR; Sigma; orMolecular Probes, Eugene, OR); heparin and CamKII 281-309 (Calbiochem);the light chain of botulinum toxin B (List Biological Labs, Campbell, CA). The concentrations of these agents in the electrodewere generally 100 times the reported IC₅₀. The botulinum toxinsolution also contained 5 mM DTT, 20 mM sodium phosphate, and10 mM NaC1. In control experiments, the vehicle solution wasinjected into the neuron. The injection was terminated whenthe cell body was visibly green and began to swell. The electrodewas then removed and replaced with a stimulating (sensory neuron)or recording (motor neuron) electrode, and the preparationwas rested 30 min before the experiment began.
Data analysis. Drug experiments were compared with interleaved control experiments. The data were normalized to the first EPSPand are presented as mean ± SEM. The normalized datawere analyzed with two or three-way ANOVA with one repeatedmeasure (time), followed by planned comparisons of the individualgroups if there were more than two. p < 0.05 is consideredsignificant.

   Results

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Homosynaptic potentiation is long-lasting
Because the sensory-motor neuron PSPs undergo homosynaptic depressionas well as potentiation, the potentiation must be assessedin comparison with a test-alone (depression) control group.In agreement with previous studies (Eliot et al., 1994a,b; Bao et al., 1997), testing the PSP even once every 5 min producedsubstantial depression (84 ± 2% of the first PSP onthe second test and 48 ± 2% on the ninth test, 40 min after the first PSP) (Fig. 1C,D). Tetanic stimulation of thesensory neuron (20 Hz, 2 sec) 9 min after the first PSP producedhomosynaptic potentiation that was significant compared withthe depression control overall (F_(1,154) = 108.40; p < 0.0001)and at every time point for 30 min after the tetanus (p <0.01 in each case). Compared with the depression control, thePSP was approximately doubled 1 min after the tetanus, andthe potentiation then decayed with a time constant of $~$ 30 min.Neither the potentiation nor the depression from 10 to 40 min correlated significantly with the amplitude of the PSP on thepretest (r = -0.123 and -0.081, respectively). However, thedepression at 5 min did correlate with the pretest, with lessdepression when the pretest was larger (r = 0.266; p < 0.001).These results suggest that the early and later phases of depressionmay involve somewhat different mechanisms.
Homosynaptic potentiation does not require Ca²⁺ influx through NMDA receptor channels or voltage-gated Ca²⁺channels
Because the potentiation lasts >30 min (Fig. 1D) and is reduced by postsynaptic BAPTA or hyperpolarization (Bao etal., 1997), it has similarities to LTP in mammals (Bliss and Collingridge, 1993) and Aplysia (Lin and Glanzman, 1994a,b). We, therefore, tested whether the potentiation involves similarsources of calcium.
We first examined the role of Ca²⁺ influx through NMDA-typeglutamate receptor channels, which is usually required for LTPin the CA1 region of hippocampus (Bliss and Collingridge,1993). The PSPs at the sensory-motor neuron synapses are thoughtto be glutamatergic and to have NMDA-like properties (Daleand Kandel, 1993), and a competitive antagonist of NMDA receptors,APV (50 µM), blocks LTP at these synapses (Lin and Glanzman, 1994b). However, APV at the same concentration had no significant effect on homosynaptic potentiation (Fig. 2A).

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Figure 2. Homosynaptic potentiation does not require Ca²⁺ influx through NMDA receptor channels or voltage-dependent Ca²⁺ channels. A, Homosynaptic potentiation is not affected by an antagonist of NMDA-type glutamate receptors, APV (50 µM). B, Homosynaptic potentiation is not affected by an inhibitor of L-type Ca²⁺ channels, nitrendipine (10 µM). C, Homosynaptic potentiation is also not affected by reducing extracellular Ca²⁺ from 10 to 2 mM. D, Homosynaptic potentiation is reduced by an antagonist of type I metabotropic glutamate receptors, LY367385 (300 µM).

LTP produced with stronger induction protocols has a non-NMDAcomponent both in CA1 hippocampus (Bliss and Collingridge,1993) and in Aplysia (Lin and Glanzman, 1994b). In hippocampus,this component involves L-type voltage-dependent calcium channels.However, nitrendipine (10 µM), which blocks $~$ 90% of theL-type current in Aplysia (Eliot et al., 1993), also had nosignificant effect on homosynaptic potentiation (Fig. 2B).
To test whether Ca²⁺ influx through some other type of channelmight be important, we examined homosynaptic potentiation with extracellular Ca²⁺ reduced from 10 to 2 m_M. Decreasing extracellularCa²⁺ decreased the amplitude of the initial PSP, as expected(Table 1), and also decreased short-term depression duringthe tetanus (fifth/first PSP = 39.3 vs 13.1% in normal Ca²⁺; t₍₁₆₎ = 2.68; p < 0.05), perhaps because of an increasein opposing frequency facilitation (Creager et al., 1980). However, reducing extracellular Ca²⁺ had no significant effecton homosynaptic potentiation (Fig. 2C). Thus, unlike PTP atfrog neuromuscular junction (Rosenthal, 1969) and either PTPor LTP in CA1 hippocampus (Dunwiddie and Lynch, 1979; Anwylet al., 1988; Mulkeen et al., 1988), homosynaptic potentiationat the Aplysia sensory-motor neuron synapses does not dependimportantly on the magnitude of Ca²⁺ influx during the tetanus.

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Table 1. Effects of drugs that did or did not reduce homosynaptic potentiation on some additional measures of plasticity

Another possible source of Ca²⁺ is through stimulation of metabotropicglutamate receptors, which also play an important role in LTPin hippocampus (Bashir et al., 1993). An inhibitor of typeI metabotropic receptors, LY367385 (300 µM) significantlyreduced homosynaptic potentiation (F_(1,13) = 7.95; p < 0.02) (Fig. 2D), suggesting that metabotropic receptors may playan important role in this potentiation as well.
Homosynaptic potentiation involves Ca²⁺ release from intracellular stores
In mammals, type I metabotropic glutamate receptors are linkedto the release of Ca²⁺ from intracellular stores. An inhibitor of endoplasmic reticulum ATPase, thapsigargin (10 µM),which depletes intracellular Ca²⁺ stores, greatly reduced homosynaptic potentiation (F_(1,32) = 34.95; p < 0.001) (Fig. 3A,B), suggesting that Ca²⁺ release from intracellular storesplays an important role in the potentiation. There was no significantinteraction between the effect of thapsigargin and time, suggestingthat intracellular Ca²⁺ release is important for both the earlyand late phases of potentiation.

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Figure 3. Homosynaptic potentiation involves Ca ²⁺ release from both IP₃- and ryanodine-sensitive intracellular stores. A, Examples of the PSPs in a representative potentiation experiment and a depression control experiment during perfusion with thapsigargin (10 µM), which depletes intracellular Ca²⁺ stores. B, Average results from experiments like these shown in A. Homosynaptic potentiation is greatly reduced by thapsigargin, compared with the no drug control experiments. Thapsigargin also tended to increase homosynaptic depression on the second test, 5 min after the first PSP, but had no significant effect on the depression from 10 to 40 min. There was a significant drug x tetanus interaction (F_{(1,
32)} = 13.83; p < 0.001) in a three-way ANOVA with one repeated measure (time) for the data from 10 to 40 min. C, Homosynaptic potentiation is greatly reduced by a cell permeable inhibitor of IP₃ receptors, 2APB (10 µM). D, Homosynaptic potentiation is reduced by prolonged application of a relatively high concentration (100 µM) of ryanodine, which blocks ryanodine receptors. Inset, Brief application of a relatively low concentration (1 µM) of ryanodine (which activates ryanodine receptors) after the first PSP produced potentiation of the second PSP. The average amplitudes of the PSPs on the first test were 20.4 mV (control, n = 9) and 6.8 mV (1 µM ryanodine, n = 6); not significantly different.

There was also a trend for thapsigargin to increase homosynapticdepression on the test before the tetanus, 5 min after thefirst PSP (Table 1). However, when we ran two additional groups(test-alone or depression controls) without tetanic stimulation,we found that thapsigargin had no significant effect on the depression from 10 to 40 min. These results indicate that theeffect of thapsigargin on potentiation is not because of enhanceddepression. In the presence of thapsigargin, the potentiationgroup actually went significantly below the depression controlgroup by 40 min, in part because the PSP gradually fell tozero in six of 11 experiments in the potentiation group but none in the depression group (the PSP fell to zero in only oneof the 156 no drug experiments in Fig. 1D). The disappearanceof the PSP is not likely to be because of a failure of presynapticstimulation, because it occurred gradually, rather than abruptly.Moreover, thapsigargin still significantly reduced homosynapticpotentiation, even when the experiments with zero responseswere excluded (p < 0.01).
Thapsigargin also significantly reduced the total postsynaptic depolarization during the tetanus (area = 6,614 vs 40,661 mVx msec in the control group; t₍₁₆₎ = 5.35; p < 0.001). This effect was due in part to increased homosynaptic depressionbefore the first PSP of the tetanus (first/Pre = 71.3 vs 79.5%),similar to the increased depression on the 5 min test, andin part to increased short-term depression during the tetanus(t₍₁₆₎ = 6.26; p < 0.001) (Table 1, Fig. 4C). These resultssuggest that thapsigargin might act by reducing postsynaptic depolarization during the tetanus and, thus, blocking othervoltage-dependent mechanisms of potentiation. However, twosuch mechanisms, Ca²⁺ influx though NMDA receptor channelsor voltage-dependent Ca²⁺ channels, do not play important roles in homosynaptic potentiation (Fig. 2A,B). Furthermore,low Ca²⁺ also reduced postsynaptic depolarization during thetetanus (area = 10, 079 vs 24,419 mV x msec in the controlgroup; t₍₁₆₎ = 3.71; p < 0.01) but did not significantlyeffect potentiation (Fig. 2C). In addition, in the controlexperiments shown in Figure 1D, there was no significant correlationbetween the average percentage of potentiation and the totalpostsynaptic depolarization during the tetanus (r = 0.103). Thus, the reduction in postsynaptic depolarization cannot explainthe effect of thapsigargin on potentiation.

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Figure 4. Homosynaptic potentiation involves both presynaptic and postsynaptic Ca²⁺ release, and short-term plasticity also involves presynaptic Ca²⁺ release. A, Homosynaptic potentiation is significantly reduced by injection of a cell impermeable antagonist of IP₃ receptors (heparin, 2 mg/ml in the electrode) but not a cell impermeable antagonist of ryanodine receptors (8NcADPR, 20 µM in the electrode) into the motor neuron. B, Homosynaptic potentiation is significantly reduced by injection of 8NcADPR, but not heparin, into the sensory neuron. C, Short-term depression during the tetanus is increased by thapsigargin or a high concentration of ryanodine, but not by 2APB. The data are from the same experiments as Figure 3. To get an overall index of plasticity during the 2 sec tetanus, we measured the total area under the tetanus (in millivolts x milliseconds) normalized to the amplitude of the first PSP in the tetanus (in millivolts) in each experiment. D, Short-term depression during the tetanus is increased by presynaptic 8NcADPR but not by postsynaptic 8NcADPR or either presynaptic or postsynaptic heparin. The data are from the same experiments as A and B.

Homosynaptic potentiation involves postsynaptic IP₃ receptors and presynaptic ryanodine receptors
Thapsigargin depletes both IP₃-sensitive and ryanodine-sensitive Ca²⁺ stores. Type I metabotropic receptors are linked to theproduction of IP₃, and ryanodine receptors play an important role in Ca²⁺-induced Ca²⁺ release, suggesting that both storesmight be involved. Consistent with that idea, a cell-permeableinhibitor of IP₃ receptors, 2APB (10 µM) greatly reducedhomosynaptic potentiation (F_(1,14) = 6.69; p < 0.05) (Fig.3C). Similarly, prolonged (40 min) application of a relativelyhigh concentration (100 µM) of ryanodine, which bindsto a low-affinity site and blocks ryanodine receptors (Meissner, 1986; McPherson et al., 1991) also reduced the potentiation(F_(1,12) = 33.06; p < 0.001) (Fig. 3D). Brief (4 min) applicationof a relatively low concentration (1 µM) of ryanodine,which binds to a high-affinity site and activates ryanodinereceptors, produced potentiation of the PSP (F_(1,13) = 7.62;p < 0.05 compared with the no drug control) (Fig. 3D, inset),further supporting a role of ryanodine receptors. Like thapsigargin,a high concentration of ryanodine also increased the short-termdepression during the tetanus (t₍₁₂₎ = 2.91; p < 0.05),but 2APB did not (Table 1, Fig. 4C). These results suggestthat whereas ryanodine-sensitive Ca²⁺ stores are selectivelyinvolved in short-term plasticity during the tetanus, bothIP₃-sensitive and ryanodine-sensitive Ca²⁺ stores contributeto homosynaptic potentiation.
Because the potentiation involves Ca²⁺ in both the presynapticand postsynaptic neurons (Bao et al., 1997), Ca²⁺ release from intracellular stores in either neuron might play a role. Totest those possibilities, we injected cell impermeable antagonistsof either IP₃ receptors (heparin) or ryanodine receptors (8NcADPR)into either the sensory neuron or the motor neuron. Injectingheparin (2 mg/ml in the electrode) into the motor neuron reducedthe potentiation (F_(1,31) = 5.08; p < 0.05) (Fig. 4A).However, the reduction in potentiation was more modest thanthat produced by 2APB (Fig. 3C), perhaps because substancesinjected into the cell body reach the synapses at a much lowerconcentration. As in the thapsigargin experiments, the PSP gradually fell to zero in two of 10 experiments in the heparin group,but heparin still significantly reduced potentiation when thoseexperiments were excluded (p < 0.05; one-tail). In contrast,injecting 8NcADPR (20 µM) into the motor neuron had nosignificant effect. These results, therefore, suggest thatCa²⁺ release from postsynaptic IP₃-sensitive stores contributesto homosynaptic potentiation.
By contrast, injecting heparin into the sensory neuron did nothave a significant effect on homosynaptic potentiation (Fig.4B). However, injecting 8NcADPR into the sensory neuron didreduce the potentiation (F_(1,25) = 5.48; p < 0.05). Likethapsigargin and postsynaptic heparin, presynaptic 8NcADPRcaused the PSP to fall to zero gradually in three of 10 experiments.Like thapsigargin and ryanodine, presynaptic 8NcADPR also tendedto increase the short-term depression during the tetanus (t₍₁₉₎= 1.94; p < 0.05; one-tail) (Table 1), but postsynaptic 8NcADPR and either presynaptic or postsynaptic heparin did not (Fig. 4D). These results support the idea that presynapticryanodine receptors contribute to short-term plasticity duringthe tetanus (Narita et al., 2000; Emptage et al., 2001) and suggest that Ca²⁺ release from presynaptic ryanodine-sensitivestores also contributes to longer-lasting potentiation.
Homosynaptic potentiation involves protein kinases, probably including MAP kinase
We next began to investigate possible downstream effectors of Ca²⁺ during homosynaptic potentiation. We first tested therole of protein kinases, many of which can be activated eitherdirectly or indirectly by Ca²⁺ and contribute to hippocampalLTP (Bliss and Collingridge, 1993). A general inhibitor ofprotein kinases, K252a (200 µM) greatly reduced homosynapticpotentiation (F_(1,21) = 38.12; p < 0.001) (Fig. 5A). Therewas also a significant interaction between the effect of K252aand time, but this was eliminated by a log transformation of the data, indicating that the ratio of the control and druggroups was approximately constant over time. Like thapsigargin,K252a also increased homosynaptic depression on the secondtest, 5 min after the first PSP (F_(1,23) = 9.93; p < 0.01) (Table 1), but it had no significant effect on the depressionfrom 10 to 40 min in test-alone control experiments. Anothergeneral inhibitor of protein kinases, staurosporine (50 µM),also reduced potentiation (F_(1,13) = 15.78; p < 0.01) (Fig. 5B). These results suggest that protein phosphorylation playsan important role in the potentiation.

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Figure 5. Homosynaptic potentiation involves protein kinases, probably including MAP kinase. A, Homosynaptic potentiation is greatly reduced by a general inhibitor of protein kinases, K252a (200 nM). K252a also increased homosynaptic depression on the second test, 5 min after the first PSP, but had no significant effect on the depression from 10 to 40 min. There was a significant drug x tetanus interaction (F_(1,21) = 16.68; p < 0.001) in a three-way ANOVA with one repeated measure (time) for the data from 10 to 40 min. B, Homosynaptic potentiation is also reduced by another general inhibitor of protein kinases, staurosporine (50 nM). C, Homosynaptic potentiation is not reduced by a third general inhibitor of protein kinases, H7 (100 µM). D, Homosynaptic potentiation is reduced by an inhibitor of MAP kinase, U0126 (10 µM).

However, a third general inhibitor of protein kinases, H7 (100 µM), had no significant effect on the potentiation (Fig.5C), although a similar concentration of H7 blocks other typesof plasticity in these neurons (Braha et al., 1993). H7 isa relatively potent inhibitor of myosin light chain kinase,cAMP-dependent protein kinase (PKA), cGMP-dependent proteinkinase (PKG), and PKC in mammals, suggesting that none of thesekinases may play a critical role. However, because H7 is thoughtto be somewhat more selective for PKC in Aplysia (Braha etal., 1993), we also tested more specific inhibitors of PKA(KT5720; 2 µM; n = 9 drug and 9 control) and PKG (KT5823;1 µM; n = 4 drug and 4 control). Neither inhibitor hada significant effect on the potentiation, although at similarconcentrations they both block classical conditioning in Aplysia (Antonov et al., 2003) (I. Antonov, unpublished data).
We also performed preliminary tests of the possible roles ofsome other protein kinases that contribute to LTP in hippocampus (O'Dell et al., 1991; English and Sweatt, 1996). An inhibitorof tyrosine kinase, lavendustin A (1 µM; n = 6 and 4)had no significant effect on homosynaptic potentiation, althougha higher concentration may be necessary in Aplysia (Purcelland Carew, 2001). However, an inhibitor of MAP kinase, U0126(10 µM), which blocks vesicle mobilization in these neuronsat a similar concentration (Angers et al., 2002; Chin et al.,2002), reduced the potentiation (F_(1,15) = 17.04; p < 0.001) (Fig. 5D). These results suggest that MAP kinase may contributeto homosynaptic potentiation as well.
Homosynaptic potentiation involves both presynaptic and postsynaptic CamKII
H7 is known to differ from K252a and staurosporine in beinga relatively poor inhibitor of calcium/calmodulin-dependentprotein kinase (CamKII), suggesting that CamKII might playan important role. Consistent with that idea, a more specificinhibitor of CamKII, KN93 (5 µM), greatly reduced homosynapticpotentiation (F_(1,23) = 23.10; p < 0.001) (Fig. 6A). Therewas also a significant interaction between the effect of KN93and time, but this was eliminated by a log transformation of the data, suggesting that CamKII contributes to both early andlate potentiation. Like thapsigargin and K252a, KN93 also tendedto increase homosynaptic depression on the second test, 5 minafter the first PSP (Table 1), but it had no significant effecton the depression from 10 to 40 min in test-alone control experiments.An inhibitor of calmodulin, calmidazolium (10 µM), whichalso inhibits Cam kinase in Aplysia (DeReimer et al., 1984), reduced the potentation as well (F_(1,11) = 5.02; p < 0.05)(Fig. 6B). These results suggest the involvement of CamKIIin homosynaptic potentiation.

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Figure 6. Homosynaptic potentiation involves both presynaptic and postsynaptic CamKII. A, Homosynaptic potentiation is greatly reduced by a more specific inhibitor of CamKII, KN93 (5 µM). KN93 also tended to increase homosynaptic depression on the second test, 5 min after the first PSP, but had no significant effect on the depression from 10 to 40 min. There was a significant drug x tetanus interaction (F_(1,23) = 10.67; p < 0.01) in a three-way ANOVA with one repeated measure (time) for the data from 10 to 40 min. B, Homosynaptic potentiation is also reduced by an inhibitor of calmodulin, calmidazolium (10 µM). C, Homosynaptic potentiation is reduced by injection of a peptide inhibitor of CamKII, CamKII 281-309 (300 µM in the electrode) into the motor neuron. D, Homosynaptic potentiation is also reduced by injection of CamKII 281-309 into the sensory neuron.

To test whether CamKII acts in either the presynaptic or postsynaptic neuron, we injected a peptide inhibitor, CamKII 281-309, intoeither the sensory neuron or the motor neuron. Injecting CamKII281-309 (300 µM in the electrode) into the motor neuronreduced homosynaptic potentiation (F_(1,19) = 4.62; p < 0.05) (Fig. 6C). Injecting CamKII 281-309 into the sensory neuronalso reduced the potentiation (F_(1,19) = 5.28; p < 0.05) (Fig. 6D), suggesting that both presynaptic and postsynapticCamKII contribute to homosynaptic potentiation.
Homosynaptic potentiation does not require nitric oxide, but may involve AMPA receptor insertion
Injecting Ca²⁺ chelators (Bao et al., 1997), inhibitors ofintracellular Ca²⁺ release (Fig. 4), or inhibitors of CamKII(Fig. 6) into either the sensory neuron or the motor neuronproduces a substantial reduction in potentiation. These observationssuggest that the potentiation involves both presynaptic andpostsynaptic mechanisms, which might interact through transsynapticsignaling. Because nitric oxide (NO) synthase (NOS) is stimulatedby Ca²⁺ and NO can act as a transsynaptic messenger duringhippocampal LTP (Hawkins et al., 1998), we tested its possibleinvolvement in homosynaptic potentiation. An inhibitor of NOS, N-nitro-_L-arginine (500 µM) had no significant effecton the potentiation (Fig. 7A), although at the same concentrationit blocks classical conditioning in Aplysia (Antonov et al.,2001). Similarly, a scavenger of extracellular NO, oxymyoglobin(10 µM), also had no significant effect compared withthe inactive form, metmyoglobin (Fig. 7B). These results suggeststhat NO does not play an important role in the potentiation.Because oxymyoglobin also scavenges carbon monoxide (CO), anotherpossible transsynaptic messenger, these results suggest thatCO is not involved either.

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Figure 7. Homosynaptic potentiation does not require NO but may involve AMPA receptor insertion. A, Homosynaptic potentiation is not reduced by an inhibitor of NOS, N-nitro-L-arginine (500 µM). B, Homosynaptic potentiation is also not reduced by a scavenger of NO, oxymyoglobin (10 µM), compared with the inactive form, metmyoglobin. C, Homosynaptic potentiation is greatly reduced by an antagonist of AMPA-type glutamate receptors, DNQX (5 µM). DNQX also increased homosynaptic depression on the second test, 5 min after the first PSP, but had no significant effect on the depression from 10 to 40 min. There was a significant drug x tetanus interaction (F_(1,22) = 10.68; p < 0.01) in a three-way ANOVA with one repeated measure (time) for the data from 10 to 40 min. D, Homosynaptic potentiation is also reduced by injection of the light chain of botulinum toxin type B (0.5 µM in the electrode), which blocks exocytocis, into the motor neuron.

Both CamKII and MAP kinase contribute to LTP in hippocampusthrough insertion of AMPA-type glutamate receptors into thepostsynaptic membrane (Malinow and Malenka, 2002). Aplysiasensory-motor neuron PSPs are thought to have both AMPA and NMDA components (Glanzman, 1994; Conrad et al., 1999; Antonovet al., 2003), and insertion of AMPA-type receptors may alsocontribute to facilitation by serotonin in Aplysia (Chitwoodet al., 2001). To begin to test whether that mechanism contributesto homosynaptic potentiation as well, we examined potentiationin the presence of a low concentration (5 µM) of theAMPA receptor antagonist DNQX, which should decrease the importanceof any selective changes in the AMPA component. DNQX greatly reduced homosynaptic potentiation (F_(1,22) = 17.70; p <0.001) (Fig. 7C). Like thapsigargin, K252a, and KN93, DNQXalso increased homosynaptic depression on the second test,5 min after the first PSP (F_(1,24) = 5.16; p < 0.05) (Table 1),but it had no significant effect on the depression from10 to 40 min in test alone control experiments. In the presenceof DNQX, the potentiation group went significantly below thedepression control group by 40 min, in part because the PSPgradually fell to zero in two of seven experiments in the potentiation group but none in the depression group. However, the potentiationgroup still went significantly below the depression controlgroup even when the experiments with zero responses were excluded.As expected, DNQX also reduced the amplitude of the initialPSP (Table 1) and the postsynaptic depolarization during thetetanus (area = 7,119 vs 28,755 mV x msec in the control group).However, these effects probably do not explain the reductionin homosynaptic potentiation, because low Ca²⁺ had similareffects without affecting the potentiation (Fig. 2C). Thelow Ca²⁺result also argues against an important role of Ca²⁺influx through Ca²⁺ permeable AMPA receptors, although thatpossibility is not ruled out.
As another way to test the role of AMPA receptor insertion,we injected the motor neuron with the light chain of botulinumtoxin type B, which blocks delivery of new receptors to thepostsynaptic membrane though exocytosis. Botulinum toxin (0.5µM in the electrode) reduced homosynaptic potentiation(F_(1,18) = 12.43; p < 0.01) (Fig. 7D), consistent witha role of postsynaptic exocytosis in the potentiation. However, postsynaptic botulinum toxin also had some other unusual effects.First, there was a significant interaction between the effectof botulinum toxin and time that was not eliminated by a logtransformation of the data, suggesting that, unlike any ofthe other agents that we tested, botulinum toxin selectively affected the early phase of potentiation. Second, postsynapticbotulinum toxin also increased the amplitude of the initialPSP (t₍₁₈₎ = 2.91; p < 0.01) (Table 1) and increased short-termdepression during the tetanus (t₍₁₇₎ = 2.71; p < 0.05) (Table 1). Although botulinum toxin still significantly reducedhomosynaptic potentiation when these effects were factoredout in ANCOVA, they suggest that the toxin may not act simplyby blocking AMPA receptor insertion. The effects on the amplitudeand short-term depression of the PSP are the reverse of thosewith low Ca²⁺ (Fig. 2C), suggesting that postsynaptic botulinumtoxin may increase the presynaptic probability of release (perhapsby blocking release of an inhibitory retrograde signal). Thus,although our results tend to support the possible involvementof AMPA receptor insertion in homosynaptic potentiation, botulinumtoxin may also affect other mechanisms.

   Discussion

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Mechanisms of homosynaptic potentiation
Bao et al. (1997) previously found that homosynaptic potentiationat Aplysia sensory-motor neuron synapses in isolated cell cultureinvolves both presynaptic and postsynaptic Ca²⁺. We have nowinvestigated the sources of Ca²⁺ and some of its downstreamtargets. Our results suggest that the potentiation involvesintracellular Ca²⁺ release from both postsynaptic IP₃-sensitiveand presynaptic ryanodine-sensitive stores (Figs. 3, 4) andalso both presynaptic and postsynaptic CamKII and probablyMAP kinase (Figs. 5, 6). In addition, the potentiation mayinvolve postsynaptic AMPA receptor insertion (Figs. 7C,D). Intracellular Ca²⁺ release and CamKII are similarly thoughtto play some role in the spike broadening-independent componentof facilitation by serotonin at Aplysia sensory-motor neuronsynapses (Boyle et al., 1984; Nakanishi et al., 1997), and AMPA receptor insertion may also contribute to facilitationby serotonin in the same time range as the potentiation (around30 min) (Chitwood et al., 2001; Li et al., 2001). Like homosynapticpotentiation, AMPA receptor insertion is thought to involve metabotropic receptors linked to Ca²⁺ release from postsynapticIP₃-sensitive stores in Aplysia (Chitwood et al., 2001; Liand Glanzman, 2002) and postsynaptic CamKII and MAP kinasein hippocampus (Malinow and Malenka, 2002). However, becausethe agents that we used to test the possible role of AMPA receptorinsertion in homosynaptic potentiation (DNQX and botulinum toxin)may have had additional actions, it will be necessary to testthat idea with other methods.
In the presence of a few of the drugs that we used (thapsigargin, postsynaptic heparin, presynaptic 8NcADPR, and DNQX), the PSPgradually fell to zero in some of the experiments in the tetanusgroup but not in the depression control group. This resultsuggests that the tetanus caused depletion of some factor thatcould not be restored in the presence of the drug. Becausethese drugs had both presynaptic and postsynaptic actions, at least two hypotheses seem possible: (1) the drugs might causedepletion of AMPA receptors by blocking receptor insertion,if the tetanus stimulates both insertion and removal; and (2)they might cause depletion of presynaptic vesicles by blockingvesicle mobilization. Like homosynaptic potentiation, vesiclemobilization is thought to involve Ca²⁺ release from intracellularstores (Kuromi et al., 2002) and phosphorylation by MAP kinasein Aplysia (Angers et al., 2002; Chin et al., 2002) and byCamKII in vertebrates (Greengard et al., 1993).
Our experiments also provide some information about mechanismsof homosynaptic depression. Notably, almost all of the drugsthat decreased homosynaptic potentiation also increased homosynapticdepression on the second test, 5 min after the first PSP (Table 1),but the representative drugs that we tested more fully (a general inhibitor of intracellular Ca²⁺ release, thapsigargin;a general inhibitor of protein kinases, K252a; a more selective inhibitor of CamKII, KN93; and an AMPA receptor antagonist,DNQX) did not affect the depression from 10 to 40 min, indicatingthat their effects on potentiation are not because of enhanceddepression. Chin et al. (2002) made a similar observationwith the MAP kinase inhibitor U0126. In addition, we found that the amplitude of the PSP on the first test had a significantnegative correlation with the 5 min depression but not thedepression from 10 to 40 min. One possible explanation forthese results is that the first test transiently engages thesame mechanisms of potentiation as the tetanus, and these counteractthe depression at 5 min. An additional implication of these results is that the depression from 10 to 40 min does not involveany of the mechanisms that we tested.
Comparison with other forms of homosynaptic potentiation
We have previously referred to the potentiation produced withthis protocol (20 Hz, 2 sec tetanus at Aplysia sensory-motorneuron synapses in isolated cell culture) as PTP because itshares many features with PTP in other systems: it is producedby rather mild tetanic stimulation and is accompanied by anincrease in the frequency of spontaneous miniature EPSPs withno change in their amplitude (Eliot et al., 1994b), and itis blocked by presynaptic EGTA (Bao et al., 1997) but not by APV (Kononenko and Hawkins, 1998). These features are all consistentwith residual presynaptic Ca²⁺, which is thought to be theprimary mechanism of PTP at most synapses (Zucker and Regehr, 2002). Furthermore, like potentiation at the sensory-motor neuron synapses, PTP in some systems involves Ca²⁺ release from presynapticryanodine sensitive stores (Narita et al., 2000) and may alsoinvolve presynaptic CamKII (Greengard et al., 1993; cf. Zuckerand Regehr, 2002). In addition, the potentiation was originally thought to last 10 -15 min, which is within the range of PTP.
However, more careful analysis of group data (Fig. 1D) showsthat the potentiation lasts >30 min, which is in the rangethat is usually referred to as LTP. Moreover, like LTP in theCA1 region of hippocampus (Bliss and Collingridge, 1993) orLTP produced by a stronger stimulation protocol at Aplysia sensory-motor neuron synapses (Lin and Glanzman, 1994a,b), the potentiation is reduced by postsynaptic BAPTA or hyperpolarization (Bao et al., 1997). Potentiation with a similar protocol inthe ganglion can also be reduced by postsynaptic BAPTA (Schaffhausenet al., 2001). Like CA1 LTP (Malinow and Malenka, 2002), thepotentiation also involves MAP kinase and postsynaptic CamKII(Figs. 5, 6), and it may involve postsynaptic AMPA receptorinsertion (Fig. 7). However, unlike LTP in CA1 hippocampusor Aplysia, the potentiation is not blocked by APV (Fig. 2A),and it is also not blocked by inhibition of L-type voltage-dependent Ca²⁺ channels (Fig. 2B).
The potentiation, thus, has similarities with either PTP orLTP in CA1 hippocampus, but it seems to differ from both becauseit is not significantly affected by a fivefold reduction inextracellular Ca²⁺ (Dunwiddie and Lynch, 1979; Anwyl et al.,1988; Mulkeen et al., 1988) (Fig. 2C), although the normalCa²⁺ level is also higher in Aplysia. Furthermore, unlike PTPand LTP in CA1, the early (1 min) and late (30 min) parts ofthe potentiation are not differentially affected by any ofthe drugs that we have tested, as indicated by the lack of a significant drug x time interaction on the log transformed data(with the exception of postsynaptic botulinum toxin) (Fig.7D). For these reasons, we now refer to the increase in theEPSP with the more neutral term, "homosynaptic potentiation."
Because homosynaptic potentiation involves metabotropic glutamatereceptors linked to Ca²⁺ release from intracellular stores(Figs. 2D, 3, 4A), it may be more similar to LTP onto hippocampalinterneurons (Woodhall et al., 1999; Perez et al., 2001). Metabotropic receptors linked to Ca²⁺ release also contributeto CA1 LTP (Bortolotto and Collingridge, 1993; Wilsch et al.,1998) and may play a role in mossy fiber LTP as well (Yeckelet al., 1999; Kapur et al., 2001). Homosynaptic potentiationalso has mechanistic similarities to hippocampal LTD, whichis thought to involve intracellular Ca²⁺ release from bothpostsynaptic IP₃-sensitive stores and presynaptic ryanodine-sensitivestores (Reyes and Stanton, 1996; Reyes-Harde et al., 1999a,b; Unni and Siegelbaum, 2001), leading to activation of presynapticCamKII (Stanton and Gage, 1996). These presynaptic and postsynapticmechanisms are believed to be linked by retrograde signalingthrough the NO-cGMP-PKG pathway (Gage et al., 1997; Reyes-Hardeet al., 1999a,b), and plasticity at Aplysia sensory-motorneuron synapses during classical conditioning also involvesretrograde signaling (Antonov et al., 2003). It is not yetknown whether homosynaptic potentiation similarly involves retrograde signaling, but it evidently does not involve the NO-cGMP-PKGpathway (Fig. 7A,B).
Homosynaptic potentiation at Aplysia sensory-motor neuron synapses,thus, shares components of the mechanisms of a variety of other forms of homosynaptic plasticity including PTP, LTP, and LTD,but does not appear to be identical to any of them. These resultssupport the idea that there is a molecular alphabet of componentsthat can be combined in various ways to create a wide rangeof different types of plasticity with different functionalproperties. An implication of this idea is that the differenttypes of plasticity may have evolved in this way to serve differentfunctional purposes. The behavioral function of homosynapticpotentiation in Aplysia is still uncertain, but when the potentiationoccurs at the same time as presynaptic facilitation by serotonin,the two types of plasticity interact to create an associativemechanism, activity-dependent enhancement of presynaptic facilitationthat is thought to contribute to classical conditioning (Eliotet al., 1994a; Bao et al., 1998; Antonov et al., 2003). Likehomosynaptic potentiation, activity-dependent presynaptic facilitationin isolated cell culture can be blocked by presynaptic EGTA,postsynaptic BAPTA, or strong postsynaptic hyperpolarization,but unlike homosynaptic potentiation, it can also be blockedby a presynaptic inhibitor of PKA (Bao et al., 1997, 1998).Thus, activity-dependent presynaptic facilitation appears tocombine some of the mechanisms of homosynaptic potentiationwith those of presynaptic facilitation (the PKA pathway). Atestable prediction of this idea is that activity-dependent presynaptic facilitation may also involve the additional mechanismsof homosynaptic potentiation that we have described, includingintracellular Ca²⁺ release, CamKII, MAP kinase, and possiblyAMPA receptor insertion, and that these may in turn contributeto some of the functional properties of classical conditioningin Aplysia.

   Footnotes

Received Apr. 15, 2003; revised Jun. 18, 2003; accepted Jun. 18, 2003.
This work was supported by National Institutes of Mental HealthGrant MH26212. We thank E. R. Kandel and S. A. Siegelbaum forcomments and B. Robertson for typing this manuscript.
Correspondence should be addressed to Dr. Robert Hawkins, Centerfor Neurobiology and Behavior, Columbia University, 1051 RiversideDrive, New York, NY 10032. E-mail: rdh1{at}columbia.edu.
Copyright © 2003 Society for Neuroscience 0270-6474/03/237288-10$15.00/0

   References

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Angers A, Fioravante D, Chin J, Cleary LJ, Bean AJ, Byrne JH (2002) Serotonin stimulates phosphorylation of Aplysia synapsin and alters its sub-cellular distribution in sensory neurons. J Neurosci 22: 5412-5422.[Abstract/Free Full Text]
Antonov I, Antonova I, Minnal A, Hawkins RD (2001) Possible interaction of pre- and postsynaptic mechanisms during classical conditioning in Aplysia. Soc Neurosci Abstr 27: 954.15.
Antonov I, Antonova I, Kandel ER, Hawkins RD (2003) Activity-dependent presynaptic facilitation and Hebbian LTP are both required and interact during classical conditioning in Aplysia. Neuron 37: 135-147.[ISI][Medline]
Anwyl R, Lee WL, Rowan M (1988) The role of calcium in short-term potentiation in the rat hippocampal slice. Brain Res 459: 192-195.[Medline]
Bao JX, 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]
Bao JX, Kandel ER, Hawkins RD (1998) Involvement of presynaptic and postsynaptic mechanisms in a cellular analog of classical conditioning at Aplysia sensory-motor neuron synapses in isolated cell culture. J Neurosci 18: 458-466.[Abstract/Free Full Text]
Bashir ZI, Bartolotto ZA, Davies CH, Berretta N, Irving AJ, Seal AJ, Henley JM, Jane DE, Watkins JC, Collingridge GL (1993) Induction of LTP in the hippocampus needs synaptic activation of glutamate metabotropic receptors. Nature 363: 347-350.[Medline]
Bliss TVP, Collingridge GL (1993) A synaptic model of memory: long-term potentiation in hippocampus. Nature 361: 31-39.[Medline]
Bortolotto ZA, Collingridge GL (1993) Characterization of LTP induced by the activation of glutamate metabotropic receptors in area CA1 of the hippocampus. Neuropharmacology 3: 1-9.
Boyle MB, Klein M, Smith SJ, Kandel ER (1984) Serotonin increases intracellular Ca ²⁺ transients in voltage-clamped sensory neurons of Aplysia californica. Proc Natl Acad Sci USA 81: 7642-7646.[Abstract/Free Full Text]
Braha O, Edmonds B, Sacktor T, Kandel ER, Klein M (1993) The contributions of protein kinase A and protein kinase C to the actions of 5-HT on the L-type Ca ²⁺ current of the sensory neurons in Aplysia. J Neurosci 13: 1839-1851.[Abstract]
Chin J, Angers A, Cleary LJ, Eskin A, Byrne JH (2002) Transforming growth factor ${beta}$ 1 alters synapsin distribution and modulates synaptic depression in Aplysia. J Neurosci 22: RC220(1-6).[Abstract/Free Full Text]
Chitwood RA, Li Q, Glanzman DL (2001) Serotonin facilitates AMPA-type responses in isolated siphon motor neurons of Aplysia in culture. J Physiol (Lond) 534: 501-510.[Abstract/Free Full Text]
Conrad P, Wu F, Schacher S (1999) Changes in functional glutamate receptors on a postsynaptic neuron accompany formation and maturation of an identified synapse. J Neurobiol 39: 237-248.[ISI][Medline]
Creager R, Dunwiddie T, Lynch G (1980) Paired-pulse and frequency facilitation in the CA1 region of the in vitro rat hippocampus. J Physiol (Lond) 299: 409-424.[Abstract/Free Full Text]
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]
DeReimer SA, Kaczmarek LK, Lai Y, McGuiness TL, Greengard P (1984) Calcium calmodulin-dependent protein phosphorylation in the nervous system of Aplysia. J Neurosci 4: 1618-1625.[Abstract]
Dunwiddie TV, Lynch G (1979) The relationship between extracellular calcium concentrations and the induction of hippocampal long-term potentiation. Brain Res 169: 103-110.[ISI][Medline]
Eliot LS, Kandel ER, Siegelbaum SA, Blumeneld H (1993) Imaging terminals of Aplysia sensory neurons demonstrates role of enhanced Ca ²⁺ influx in presynaptic facilitation. Nature 361: 634-637.[Medline]
Eliot LS, Hawkins RD, Kandel ER, Schacher S (1994a) Pairing-specific, activity-dependent presynaptic facilitation at 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]
Emptage NJ, Reid CA, Fine A (2001) Calcium stores in hippocampal synaptic boutons mediate short-term plasticity, store-operated Ca ²⁺ entry, and spontaneous transmitter release. Neuron 29: 197-208.[ISI][Medline]
English JD, Sweatt JD (1996) Activation of p42 mitogen-activated protein kinase in hippocampal long-term potentiation. J Biol Chem 271: 24329-24332.[Abstract/Free Full Text]
Gage AT, Reyes M, Stanton PK (1997) Nitric-oxide-guanylyl-cyclase-dependent and independent components of multiple forms of long-term synaptic depression. Hippocampus 7: 286-295.[ISI][Medline]
Glanzman DL (1994) Postsynaptic regulation of the development and long-term plasticity of Aplysia sensorimotor synapses in cell culture. J Neurobiol 25: 666-693.[ISI][Medline]
Greengard P, Valtorta F, Czenik AJ, Benfenati F (1993) Synaptic vesicle phosphoproteins and regulation of synaptic function. Science 259: 780-785.[Abstract/Free Full Text]
Hawkins RD, Son H, Arancio O (1998) Nitric oxide as a retrograde messenger during long-term potentiation in hippocampus. Prog Brain Res 118: 155-172.[ISI][Medline]
Kapur A, Yeckel M, Johnston D (2001) Hippocampal mossy fiber activity evokes Ca ²⁺ release in CA3 pyramidal neurons via a metabotropic glutamate receptor pathway. Neuroscience 107: 59-69.[ISI][Medline]
Kononenko N, Hawkins RD (1998) PTP at Aplysia sensory-motor neuron synapses in isolated cell culture does not involve NMDA receptors or nitric oxide signaling. Soc Neurosci Abstr 24: 1189.
Kuromi H, Kidokoro Y (2002) Selective replenishment of two vesicle pools depends on the source of Ca ²⁺ at the Drosophila synapse. Neuron 35: 333-343.[ISI][Medline]
Lev-Ram V, Makings LR, Keitz PF, Kao JPY, Tsien RY (1995) Long-term depression in cerebellar Purkinje neurons results from coincidence of nitric oxide and depolarization-induced Ca ²⁺ transients. Neuron 15: 407-415.[ISI][Medline]
Li Q, Glanzman DL (2002) The role of IP3 receptor-mediated calcium release from postsynaptic intracellular stores in serotonin-induced facilitation of Aplysia sensorimotor synapses. Soc Neurosci Abstr 28: 376.8.
Li Q, Villareal G, Glanzman DL (2001) The role of postsynaptic calcium and postsynaptic exocytosis in serotonin-induced facilitation of Aplysia sensorimotor synapses. Soc Neurosci Abstr 27: 954.10.
Lin XY, Glanzman DL (1994a) Long-term potentiation of Aplysia sensorimotor synapses in cell culture: regulation by postsynaptic voltage. Proc R Soc Lond B Biol Sci 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 B Biol Sci 255: 215-221.[Medline]
Malinow R, Malenka RC (2002) AMPA receptor trafficking and synaptic plasticity. Annu Rev Neurosci 25: 103-126.[ISI][Medline]
McPherson PS, Kim YK, Valdivia H, Knudson CM, Takekura H, Franzini-Armstrong C, Coronado R, Campbell KP (1991) The brain ryanodine receptor: a caffeine-sensitive calcium release channel. Neuron 7: 17-25.[ISI][Medline]
Meissner G (1986) Ryanodine activation and inhibition of the Ca ²⁺ release channel of sarcoplasmic reticulum. J Biol Chem 261: 6300-6306.[Abstract/Free Full Text]