Regulation of Spike Initiation and Propagation in an Aplysia Sensory Neuron: Gating-In via Central Depolarization

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The Journal of Neuroscience, April 1, 2003, 23(7):2920

Regulation of Spike Initiation and Propagation in an Aplysia Sensory Neuron: Gating-In via Central Depolarization
Colin G. Evans¹^,², Jian Jing¹, Steven C. Rosen³, and Elizabeth C. Cropper¹
¹ Department of Physiology and Biophysics, Mount Sinai School of Medicine, New York, New York 10029, ² Phase Five Communications Inc., New York, New York 10011, and ³ Center for Neurobiology and Behavior, Columbia University, New York, New York 10032

  ABSTRACT

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Afferent transmission can be regulated (or gated) so that responses to peripheral stimuli are adjusted to make them appropriatefor the ongoing phase of a motor program. Here, we characterizea gating mechanism that involves regulation of spike propagationin Aplysia mechanoafferent B21. B21 is striking in that afferenttransmission to the motor neuron B8 does not occur when B21 isat resting membrane potential. Our data suggest that this resultsfrom the fact that spikes are not actively propagated to the lateralprocess of B21 (the primary contact with B8). When B21 is peripherallyactivated at its resting potential, electrotonic potentials inthe lateral process are on average 11 mV. In contrast, mechanoafferentactivity is transmitted to B8 when B21 is centrally depolarizedvia current injection. Our data suggest that central depolarizationrelieves propagation failure. Full-size spikes are recorded inthe lateral process when B21 is depolarized and then peripherallyactivated. Moreover, changes in membrane potential in the lateralprocess affect spike amplitude, even when the somatic membranepotential is virtually unchanged. During motor programs, boththe lateral process and the soma of B21 are phasically depolarizedvia synaptic input. These depolarizations are sufficient to convertsubthreshold potentials to full-size spikes in the lateral process.Thus, our data strongly suggest that afferent transmission fromB21 to B8 is, at least in part, regulated via synaptic controlof spike initiation in the lateral process. Consequences of thiscontrol for compartmentalization in B21 are discussed, as arespecific consequences for feedingbehavior.

Key words: sensorimotor integration; sensory gating; central pattern generator; mollusc; feeding; motor program

  Introduction

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Many motor behaviors are mediated by networks, central pattern generators (CPGs) that can generate rhythmic output in theabsence of afferent input (Delcomyn, 1980; Marder, 2001). However,physiologically, CPGs often receive sensory input so that outputis adjusted to compensate for changes in the periphery (Rossignolet al., 1988; Pearson, 1993; Marder, 2001; McCrea, 2001; Susterand Bate, 2002). When this occurs, changes in motor output arenot always solely determined by stimulus properties. Instead,peripherally generated and centrally generated activity can beintegrated so that stimulus-induced changes in motor output dependon the state of the ongoing motor program (Pearson and Ramirez,l997; McCrea, 2001). Thus, afferent transmission can be regulated(i.e., gated) during an ongoing motorprogram.

Mechanisms that gate-out afferent activity have been characterized most extensively. For example, terminals of sensory neuronscan be rhythmically depolarized during motor programs at leastin part via a conductance increase. When this occurs, spike amplitudeand/or transmitter release can be decreased and afferent transmissioncan be inhibited (Clarac and Cattaert, 1996; Rudomin, 1999; Cattaertet al., 2001). Although this form of control has been describedin a number of contexts, it is becoming increasingly apparentthat afferent transmission can be gated via a number of diversemechanisms (Sillar, 1991; Pearson and Ramirez, l997; DiCaprio,1999; Gosgnach et al., 2000). In this study, we characterize amechanism that gates-in rather than gates-out afferentactivity.

Studies of afferent gating are often limited by technical difficulties. Consequently, a number of studies of afferent transmissionhave been performed in experimentally advantageous invertebratepreparations. We use one such preparation and study sensory neuronsactivated during feeding in the mollusc Aplysia (Evans and Cropper,1998; Evans et al., 1999). These neurons have features that facilitatestudies of afferent transmission. For example, their somata arecentrally rather than peripherally located, which makes them easilyreidentifiable. Their major processes are also relatively largeand can be impaled with standardmicroelectrodes.

The neuron in this study, B21, is a bipolar mechanoafferent that innervates a muscle, the subradula tissue (SRT) (Cropperet al., 1996; Rosen et al., 2000) (see Fig. 1B). The SRT underliesthe radula, a structure used to move food into the buccal cavityof Aplysia. In this study, we concentrate on one of the outputconnections of B21, its excitatory chemical connection with aradula-closer motor neuron (B8) (Klein et al., 2000; Rosen etal., 2000). When B21 is peripherally activated at its restingmembrane potential, postsynaptic potentials (PSPs) are not observedin B8 (Rosen et al., 2000). In contrast, if B21 is centrally depolarizedand then peripherally activated, PSPs are observed in B8 (Rosenet al., 2000). Thus, B21 afferent transmission to B8 must be activelygated-in. Preliminary data have provided insights into how gatingmay occur (Borovikov et al., 2000; Rosen et al., 2000). In thisstudy, we verify and extend previous hypotheses. Moreover, wepresent data that indicate that afferent transmission is regulatedduring physiologically characterized motorprograms.

  Materials and Methods

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Animals. Experiments were conducted with 23 200-300 gm Aplysia californica (Marinus, Long Beach, CA) that had been maintainedin 14-16°C holding tanks. Animals were anesthetized by injectionof isotonic MgCl₂ and then dissected to create the reduced preparationsdescribed below. The nomenclature follows that of Gardner (1971).All experiments were conducted in artificial seawater composedof the following (in mM): 460 NaCl, 10 KCl, 11 CaCl₂, 55 MgCl₂,and 5 NaHCO₃.

Identification of B21. B21 was identified as described previously (Rosen et al., 2000). The average resting potential of B21(measured in its soma) was $-$ 63.8 ± 1.7 mV, and the average thresholdfor spike initiation when current was injected into the soma was $-$ 35.6 ± 1.8 mV (n =5).

Preparations. Most experiments were conducted in preparations that consisted of the two buccal hemi-ganglia and the isolatedSRT. The buccal mass was dissected so that the SRT could be removedfrom beneath the radula. Because the sensory innervation of theSRT passes through the radula nerve, this nerve was left intact(Borovikov et al., 2000). All other buccal nerves were severed.In motor-program experiments, preparations also included the cerebralganglion and the cerebral buccalconnectives.

Electrophysiology. Up to four simultaneous intracellular recordings were amplified and displayed using Getting Model 5A amplifiers(Getting Instruments, Iowa City, IA) modified for 100 nA currentinjection, Tektronix (Wilsonville, OR) AM 502 amplifiers, a fourchannel Tektronix storage oscilloscope (model 5111), and an eightchannel Astro-Med chart recorder (model 9500; Grass Instruments,Quincy, MA). Some data were digitized using a Digidata (Axon Instruments,Foster City, CA) and were acquired using Axograph software (AxonInstruments) and a Macintosh G3 computer. Data were filtered electronicallywith a 1 kHz high-pass filter, and PSP recordings were filtereddigitally with Axograph. To record from the somata of neurons,we used single-barrel electrodes fabricated from thin-walled glasscapillary tubing filled with 2 M potassium acetate. Electrodeswere beveled so that their impedances were generally 5-10 M $Omega$ .To record from the lateral or medial process of B21, microelectrodeshad a high resistance (generally ~50 M $Omega$ ) and contained 3% 5(6)-carboxyfluoresceindye in 0.1 M potassium citrate (to verify recording sites as describedbelow). Specifically, electrodes were backfilled by briefly touchingthe blunt end to the carboxyfluorescein solution. With this method,only the pulled tip of the electrode was filled with dye. To depolarizeor hyperpolarize cells, DC was manually injected. When a currentwas injected via high-resistance carboxyfluorescein electrodes,the injection was continuously adjusted to compensate for progressiveincreases in electroderesistance.

In experiments in which we recorded from the lateral process of B21, we injected fast green dye into its soma. After ~15-30min, the lateral and medial processes could be visualized. Tofacilitate penetration of the lateral process, we often removedsome of the overlying connective tissue and small cells usinga glass micropipette. Physiological experiments were initiatedby placing a microelectrode in the soma of B21. We then attemptedto penetrate the lateral processes. We assumed that we were successfulif we saw a simultaneous disturbance in the soma recording. Inaddition, we attempted to gate-in responses to peripheral stimulationand confirmed that lateral spikes were recorded after soma spikes.At the conclusion of experiments, we verified recording sitesby injecting carboxyfluorescein dye (see Fig. 1A).

Buccal motor programs. Buccal motor programs can be induced via stimulation of cerebral buccal interneurons (CBIs). Motorprograms induced by CBI-2 activity have been characterized indetail previously (Rosen et al., 1991; Church and Lloyd, 1994;Morgan et al., 2000; Sanchez and Kirk, 2000; Jing and Weiss, 2001;Morgan et al., 2002). These programs can be clearly ingestive,egestive, or "intermediate" (Jing and Weiss, 2001; Morgan et al.,2002). Programs are ingestive if radula-closer motor neurons arepredominately active during radula retraction and are egestiveif radula-closer motor neurons are predominately active duringradula protraction (Morton and Chiel, 1993a,b). In intermediate(or ambiguous) programs, radula-closer motor neurons are activeduring both protraction and retraction (Morgan et al., 2002).

In one set of experiments, we recorded intracellularly from CBI-2, one of the B4/5 neurons, the B21 soma, and the radula-closermotor neuron B8. We classified cycles of motor programs usingB8 activity (Morton and Chiel, 1993a,b; Jing and Weiss, 2001;Morgan et al., 2002). If B8 fired at <1 Hz during the first phaseof the motor program (protraction) and fired at a higher frequencyduring the second phase (retraction), we classified the cycleas ingestive. If B8 was active during protraction but fired at<1 Hz during retraction, we classified the cycle of the motorprogram as egestive. In other experiments, we recorded from CBI-2the B21 soma and the B21 lateral process. In these experiments,cycles of motor programs were classified using B4/5 activity (Jingand Weiss, 2001), which correlates negatively with B8 activity.If the B4/5 firing frequency during retraction was low (i.e.,<6 Hz), and if B4/5 was active for <50% of the duration of retraction,the cycle of the program was classified as ingestive. If B4/5fired at >13 Hz and was active for >50% of the duration of retraction,the cycle of the motor program was classified asegestive.

Peripheral stimulation of the subradula tissue. The SRT was peripherally stimulated as described previously (Cropper et al.,1996). Briefly, mechanical stimuli were delivered by means ofa mini-speaker (Quam) that had a wooden stick (tip diameter, 1mm) perpendicularly attached to the speaker membrane. Reproduciblemovements of the speaker membrane were regularly elicited by drivingthe speaker with a stimulator at ~0.5-2 Hz (Grass Instruments).

Fluorescence microscopy. Dye-filled cells were viewed with a Nikon (Tokyo, Japan) Labphot2 microscope with epifluorescenceand both trans- and epi-illumination. The microscope was equippedwith a filter set to visualize fluorescein (B-2A; EX 450-490/DM505/BA 520). Digital images were captured using a Nikon CoolPix990 camera and compiled into figures using Adobe PhotoShop andAdobe Illustrator (Adobe Systems, San Jose,CA).

Data analysis. Spike amplitude, half-width, and rise time were all measured with Axograph. Kaleidagraph (Synergy Software,Reading, PA) and StatView (SAS Institute, Cary, NC) were usedto plot data and perform statistical analyses. All values aregiven as means ±SEM.

  Results

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

When B21 is peripherally activated at its resting membrane potential, PSPs are not recorded in the follower neuron B8. However,if B21 is depolarized by injecting current into its soma, PSPsare observed (Rosen et al., 2000) (Fig. 1C1). A goal of this studywas to characterize a mechanism that could underlie this phenomenon.Depolarization does produce a progressive increase in spike amplitudeand half-width (Fig. 1C3). For example, when B21 was at its restingpotential, peripherally triggered spikes recorded in the somawere on average 35.7 ± 2.6 mV, and the half-width was 4.9 ± 0.1msec. When B21 was depolarized so that it was just below threshold,spikes were 51.6 ± 3.2 mV with a half-width of 7.4 ± 0.1 msec(both differences are statistically significant). However, theprimary point of contact between B21 and B8 appears to be thelateral process and not the soma (Borovikov et al., 2000). Wetherefore sought to determine whether changes in spike characteristicsin the soma are correlated with an effect of membrane potentialon spike characteristics in the part of B21 that contacts B8 (i.e.,the lateral process).

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Figure 1. A, Verification of lateral process recordings. The rostral surface of a buccal hemi-ganglion viewed with both epifluorescence and epi-illumination is shown. B21 was injected with fast green dye before electrophysiological experiments, and carboxyfluorescein was injected after experiments. B, B21 morphology. The medial process of B21 bifurcates and innervates the contralateral buccal ganglion and both the ipsilateral and contralateral subradula tissue (only the contralateral innervation is shown). The lateral process is the primary point of contact with the radula-closer motor neuron B8. C1-C3, Somatic depolarization gates-in B21 afferent input to the radula-closer motor neuron B8 and increases the amplitude and half-width of somatic spikes. Experiments with a current passing and recording electrode in B21 and a single electrode in B8 are shown. C1, Bottom traces, Each mechanical stimulus triggered a single spike in B21 (as monitored in the soma). Top traces, PSPs (or lack thereof) in B8. As B21 was depolarized, PSPs became apparent and progressively increased in amplitude. C2, Group data. C3, Effects of somatic depolarization on somatic spikes. Increases in amplitude and half-width were both statistically significant (two-tailed paired t test; p < 0.0001 for the half-width comparison; p = 0.0001 for the amplitude comparison).

Spike propagation at resting membrane potential

To study lateral-process spikes, we peripherally activated B21 and simultaneously recorded from the lateral process and soma.When B21 was at its resting potential, the mean amplitude of potentialsin the lateral process was 10.6 ± 1.1 mV (Fig. 2A1,B). When depolarizingcurrent was injected into the soma, the amplitude of potentialsincreased to a maximum value (50.0 ± 2.8 mV) (a statisticallysignificant difference) (Fig. 2A2,B). Amplitude was not increasedfurther with additional depolarization; therefore, we refer tothese potentials as full-size spikes. Thus, when B21 is at itsresting membrane potential, depolarizing potentials in the lateralprocess are attenuated to the point at which it would be expectedthat there would be an effect on transmitter release.

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Figure 2. Spikes are attenuated in the lateral process of B21. A1, A2, B21 was peripherally activated, and intracellular recordings were obtained at approximately the positions indicated. Recording sites are indicated with respect to a camera lucida drawing of a typical cell. A1, When B21 was at its resting potential, spikes in the lateral process were attenuated. A2, When B21 was peripherally activated and depolarizing current was injected into the soma, spikes in the lateral process were no longer attenuated. Inset, Drawing that indicates the relative position of B8, the soma of B21, the medial process (M) of B21, and the lateral process (L) of B21. B, Relationship between the amount of depolarization in the lateral process and spike amplitude in the lateral process. A different symbol is used to plot data from each preparation. When B21 was centrally depolarized, there was a statistically significant increase in spike amplitude (two-tailed paired t tests; p < 0.0001).

It is likely that potentials recorded from the lateral process are attenuated because they are passive reflections of spikesactively generated in medial parts of B21 (i.e., active spikepropagation fails). Potentials recorded in the soma of B21 aregenerally smaller in amplitude than those recorded in the medialprocess, and potentials in the lateral process are generally smallerthan those recorded in the soma (Fig. 2A1). To determine whetherelectrotonic decay occurs within the lateral process itself, weplaced one electrode in the soma of B21 and a second electrodein the lateral process. We continuously activated B21 peripherally,and moved the lateral process electrode as far laterally as possible(n = 3). In other experiments, we recorded from the soma of B21and simultaneously from two points in the lateral process (n =2) (Fig. 3). In both types of experiments, we found that whenB21 was at its resting potential, the most laterally recordedpotentials were the most attenuated (Fig. 3B,C). We did not detecta reappearance of full-size spikes as we moved laterally. Thus,our data suggest that when B21 is at its resting potential, activespike propagation fails and afferent activity is not gated-in.

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Figure 3. Spike attenuation and reflection occurs within the lateral process. A, Schematic representation of the neuron from which the data in B-D were obtained. One electrode was in the soma (S), and two electrodes were in the lateral process (NL, near lateral; FL, far lateral). B1, B2, B21 was peripherally activated at its resting potential (first part of record). Note that spikes were most attenuated at the far lateral site. Depolarizing current was injected into the soma (bar under bottom trace) and spikes became full-size at the lateral recording sites, indicating that the lateral process was not damaged. C1, C2, High-speed record of 1 and 2 in B. Each stimulus triggered two spikes in B21. When full-size spikes were recorded at the far lateral site, spikes at the near lateral and soma sites were increased in amplitude and half-width (e.g., the left spike in 2). Da-Dd, Superimposition of a-d from C. The effect of spike initiation at the far lateral site was more pronounced at the near lateral site then it was in the soma (i.e., the difference between a and b is more than that between c and d).

Spike propagation with central depolarization: gating-in of mechanoafferent activity

As discussed above, when B21 is centrally depolarized and then activated peripherally, full-size spikes are recorded fromthe lateral process (Fig. 2A2). We hypothesize that this occursbecause spike propagation no longer fails (i.e., spikes are activelygenerated in the lateral process). This model implies that thelateral process is capable of spike generation. To determine whetherthis is true, we injected current into the lateral process, andin 11 of 11 preparations found that spikes could be triggered(Fig. 4A1). In most (8 of 11) cases, we found that spikes triggeredby injecting current into the lateral process were significantlyattenuated in the soma (suggesting that somatic parts of the cellwere not contributing greatly to spike generation in these cases)(Fig. 4A1, left). Additionally, we isolated the lateral processfrom medial parts of B21 (i.e., the soma and medial process).Fast green dye was injected into B21, and the lateral processwas visualized. We then severed the connection between the lateralprocess and the soma (Fig. 4B1,B2). We impaled the isolated lateralprocess and found that spikes could be initiated by injectingdepolarizing current (n = 7) (Fig. 4B3). Thus, spikes can be initiatedin the lateral process.

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Figure 4. There are at least two sites for spike initiation in B21. A1, Spikes can be triggered by injecting current into the lateral process of B21 (bars under top traces). Left, In most preparations, spikes triggered in the lateral process were attenuated in the soma, suggesting that the soma was not making a major contribution to spike initiation. Right, To verify that the soma was not damaged, it was depolarized (bar under bottom trace), and current was injected into the lateral process. Full-size spikes were now observed in the soma. A2, Spikes can be triggered by injecting current into the soma of B21 (bars under bottom traces). Left, In 9 of 23 preparations, spikes triggered in this manner were attenuated in the lateral process, suggesting that the lateral process was not making a major contribution to spike initiation. Right, To verify that the lateral process was not damaged, it was depolarized (bar under top trace), and current was injected again into the soma. B1-B4, Spikes can be initiated in both parts of B21 when the connection between the lateral process and soma is severed. B1, Preparation in which the data in B3 were obtained and viewed with epi-illumination alone (B1) or with both epifluorescence and epi-illumination (B2). B3, Spikes could be triggered in the isolated lateral process by injecting depolarizing current (bar). B4, Spikes could also be triggered by injecting current into the isolated soma/medial process (bar).

If active spike initiation in the lateral process is important for gating-in mechanoafferent input, changes in membrane potentialin the lateral process itself (instead of the soma) should beable to affect afferent transmission. To determine whether thiswas the case, we induced afferent activity in B21 and injecteddepolarizing current in the lateral process (Fig. 5A). As expected,we did record full-size spikes in the lateral process. At restingmembrane potential, depolarizing potentials were 10.4 ± 1.7 mVin amplitude, and with depolarization, potentials were 43.8 ±4.4 mV (a statistically significant difference). We also foundthe converse to be true. If we depolarized the soma of B21 tothe point at which spikes in the lateral process were full-sizeand then injected hyperpolarizing current into the lateral process,the amplitude of depolarizing potentials was reduced from 52.9± 1.9 to 16.5 ± 1.7 mV (also a statistically significant difference)(Fig. 5B1,B2).

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Figure 5. Changes in membrane potential in the lateral process affect spike propagation. A, Depolarization of the lateral process increases spike amplitude. B21 was peripherally activated at its resting potential, and spikes in the lateral process were attenuated (first response). When depolarizing current was injected into the lateral process (bar under top trace), spike amplitude in the lateral process was increased despite the relatively small change in membrane potential in the soma. The increase was statistically significant (paired t test; p = 0.0008; n = 5). B1, B2, Hyperpolarization decreases spike amplitude. An experiment with one electrode in the soma of B21 and two in the lateral process is shown. Peripheral stimulation triggered two spikes in B21. B1a, B1b, B21 was peripherally activated and depolarized (by injecting current into the soma) so that spikes in the lateral process were full-size (first response). When hyperpolarizing current was injected into the lateral process, spike amplitude was significantly decreased (e.g., third response) (paired t test; p < 0.0001; n = 3). B2a, B2b, Responses a and b from B1 at a faster sweep speed. Note that, when spikes were full-size at the far lateral recording site, spike amplitude and half-width were increased at both the near lateral and soma recording sites.

In the latter experiments, the lateral process and the soma are necessarily connected. Theoretically, changes in membranepotential in the lateral process could therefore produce changesin membrane potential and spike generation in the soma. However,note that in these experiments, changes in membrane potentialthat affected spike amplitude in the lateral process producedvery little change in membrane potential in the soma. Specifically,the average change in somatic membrane potential was 3.0 ± 0.8mV (range, 0-6.4 mV). In fact, in some (three of five) preparations,we were able to change spike initiation in the lateral processwithout any measurable change in the somatic membrane potential.In other preparations, changes in somatic membrane potential wererelatively small. It is likely, therefore, that active processesin the soma are not necessary for spike initiation when afferentactivity is gated-in. Together, our data support the idea thatactive spike propagation fails when mechanoafferent transmissiondoes not occur, and that when mechanoafferent activity is gated-in,this propagation failure isrelieved.

The above experiments emphasize the importance of active spike initiation in the lateral process for the gating-in of mechanoafferentactivity. However, they do not indicate whether or not spikesare additionally actively triggered in the soma of B21. To verifythat spike generation in the somatic region can occur, we triggeredspikes by injecting current into the soma of B21 and simultaneouslyrecorded from the lateral process. In 9 of 23 preparations, wefound that spikes could be triggered in the soma/medial processspike-initiation zone when small attenuated potentials were recordedin the lateral process (suggesting that the lateral process wasnot contributing to spike generation) (Fig. 4A2). Additionally,when the connection between the lateral process and soma was severedin all preparations tested, we found that spikes could be triggeredby injecting current into the isolated soma/medial process (n= 7) (Fig. 4B4). Thus, there is at least one spike-initiationzone in medial parts of B21 (i.e., parts of B21 relatively isopotentialwith the soma). Therefore, there are at least two possibilitiesfor the gating-in of mechanoafferent input: (1) only the lateralspike-initiation site could be activated, or (2) the soma/medialprocess spike-initiation zone(s) and the lateral-process zone(s)could both beactivated.

It is likely that activation of the soma/medial spike-initiation zone does not occur when afferent activity is gated-in viainjection of current directly into the lateral process. Full-sizespikes can be recorded in the lateral process when the lateralprocess is depolarized, but there is very little change in somaticmembrane potential (Fig. 5A). Interestingly, however, it alsoappears that the somatic spike-initiation zone(s) is not alwaysactivated when afferent activity is gated-in via current injectioninto the soma. Spikes initiated by injecting current into thesoma of B21 always have a clear afterhyperpolarization (Fig. 4B4).In contrast, when mechanoafferent activity is gated-in via somaticdepolarization, depolarizing potentials recorded in the soma donot always have a clear afterhyperpolarization (they did not in9 of 12 preparations) (Fig. 6). These depolarizing potentialsare likely to be electrotonic potentials and not spikes. Electrotonicpotentials such as axon spikes often do not have afterhyperpolarizations.Thus, even with somatic depolarization, it appears that activationof the somatic/medial process spike-initiation site may not occur.

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Figure 6. Peripherally triggered spikes in the soma of B21 do not always have a clear afterhyperpolarization. Left, B21 was peripherally activated at its resting potential, and spikes in the lateral process were attenuated (as expected). Middle, When depolarizing current was injected into the soma, spikes in the lateral process increased in amplitude. Initially, soma spikes did not have a clear afterhyperpolarization. Right, With additional depolarization, an afterhyperpolarization became apparent in the soma spike. The dashed line indicates the resting membrane potential.

To identify a variable that could determine whether activation of the somatic/medial process spike-initiation site occurs,we varied the somatic membrane potential as we gated-in afferentactivity and determined whether somatic recordings were characterizedby an afterhyperpolarization. We found that depolarization oftenchanged a somatic recording without an afterhyperpolarizationinto a spike with a clear afterhyperpolarization (Fig. 6, middlevs right). This suggests that with relatively little somatic depolarization,the soma/medial process spike-initiation site is not always activated,possibly because it has a relatively high threshold. In fact,to initiate a spike in the soma of B21 on average, it is necessaryto depolarize cells by 27.2 ± 1.1 mV. In contrast, the lateralprocess appears to have a relatively low threshold for spike initiation(at least under conditions in which subthreshold electrotonicdepolarizations are converted to action potentials). On average,full-size spikes were recorded in the lateral process with peripheralactivation when the lateral process was depolarized by 11.8 ±0.9 mV. Thus, our data suggest that when mechanoafferent activityis gated-in, spikes must be actively generated in the lateralprocess. Additionally, they can be actively generated in the somaof B21, or the somatic spike-initiation site can be skipped. Thetype of transmission that will occur is likely to depend bothon where B21 receives synaptic input and on how much it isdepolarized.

In final mechanistic experiments that examined the gating-in of mechanoafferent activity, we returned to an issue raised previously.Namely, in experiments in which we studied afferent transmissionby recording PSPs from B8, we noted that as B21 was depolarizedand PSPs appeared in B8, we observed changes in somatic spikes.Spike amplitude and half-width were increased (Fig. 1C3). Above,we emphasize the importance of active spike generation in thelateral process for the gating-in of afferent activity. We thereforesought to determine whether changes in soma spike characteristicscould, at least in part, be caused by spike initiation in thelateral process. In these experiments, we took advantage of thefact that when somatic depolarizations are at a threshold value,the membrane potential of B21 can be held constant, and activespike initiation will occur in the lateral process when some peripheralstimuli are applied and will not occur when other stimuli areapplied (as would be expected) (Segev and Schneidman, 1999) (Fig.7A). When we compared somatic spikes that were recorded underthese conditions, we found that soma spike amplitude was increasedfrom 37.3 ± 2.3 to 39.9 ± 2 mV when lateral spikes were present.Soma spike half-width was increased from 6.1 ± 0.5 to 7.7 ± 0.6msec. The effect on half-width was statistically significant,whereas the effect on amplitude was not (paired t test; p = 0.003for the effect on half-width; p = 0.08 for the effect on amplitude).Thus, changes in somatic spikes are observed when full-size spikesare recorded in the lateral process, even when there is no changein the somatic membrane potential.

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Figure 7. Spike initiation in the lateral process affects somatic spikes. A, Experiment in which B21 was peripherally activated so that two spikes were triggered as the probe contacted the SRT (on arrow above top trace) and one spike was triggered as an "off" response (off arrow). Depolarizing current was injected into the soma so that in some cases, full-size spikes were triggered in the lateral process (e.g., both on and off responses on the left), and in other cases spikes were attenuated (e.g., the on response on the right). When a full-size spike was recorded in the lateral process, the half-width of the spike in the soma increased (e.g., on the right, compare the middle traces during the on response with the middle trace during the off response). Note that there can be a delay before spikes are initiated in the lateral process, (i.e., when medial parts of B21 spike, the lateral process is depolarized almost immediately) (left, dotted lines). Thus, the rise time of the spike in the lateral process varies. B1, B2, Changes in somatic spikes appear to be caused by spike initiation in the lateral process. B1a-B1c, Somatic spikes were generated without a lateral spike (action potential labeled a) and with a lateral spike (action potential labeled b). B2a-B2c, Superimposition of a-c from B1. Also plotted is the difference between a and b, which is indicated by a dotted line. Note that the peak obtained by the subtraction reached its maximum value after c did. C, Data from 10 preparations showing that the rise time of the spike in the lateral process and the soma spike half-width are correlated (r = 0.84).

If changes in somatic spikes were at least in part a result of spike initiation in the lateral process, we would expect thatthey would satisfy several criteria. For example, we would expectthem to be small. Spikes initiated in the lateral process producerelatively small depolarization in the soma (Fig. 4A1). To quantifychanges in somatic spikes, we subtracted somatic recordings madewhen lateral spikes were not present from somatic recordings madewhen lateral spikes were present. In all cases, we obtained relativelysmall peaks of depolarization (Fig. 7B2, dotted line). Additionally,subtracted depolarizations should peak after or with action potentialsin the lateral process. Presumably, if spiking in the lateralprocess is triggering the change in the soma spike, the changein the soma spike should not happen first. We found that subtracteddepolarizations peaked after the lateral process spiked (Fig.7B2). Thus, when spikes are initiated laterally, changes in spikecharacteristics are relatively small and peak after the lateral-processspike haspeaked.

A second prediction stems from the observation that although spike initiation in medial parts of B21 is accompanied by a virtuallysimultaneous depolarization of the lateral process (Fig. 7A, leftdotted line), in some cases the lateral process does not immediatelyspike (Fig. 7A, right dotted line, 3C, 5B2). In other systems,this pattern of depolarization has been referred to as a spikewith a "foot" (Baccus, 1998). In other peripheral responses, thereis less delay before spikes are initiated in the lateral process(Fig. 6, top middle trace). Thus, the rise time of the lateral-processspike varies. If lateral-process spike initiation does in factaffect somatic spike characteristics, it would be predicted thatdifferences in lateral-spike rise time should be correlated withdifferences in somatic spike characteristics. We found a positivecorrelation between the lateral-spike rise time and the degreeof broadening of the soma spike (Fig. 7C).

Finally, if spike initiation in the lateral process affects soma spikes, we would expect that if we inhibited spike initiationin the lateral process, we would see a change in the correspondingsomatic spike. In three preparations, we were able to block spikingby injecting hyperpolarizing current into the lateral processwith virtually no change in the somatic membrane potential (Fig.8A). In all cases, we found that spike half-width was decreasedwhen the lateral process was hyperpolarized so that lateral spikeswere not triggered (Fig. 8B,C). In summary, our data indicatethat when spikes are actively initiated in the lateral processof B21, the soma and medial parts of the cell are affected (i.e.,a type of reflection occurs). This reflection is presumably moreelectrotonic then active (i.e., reflected depolarizations aresmall and appear to be graded) (Fig. 3D). If the lateral processgenerates action potentials relatively quickly, the amplitudeof the soma spike is most likely to be affected. If the lateralprocess spikes with a delay, the half-width of the soma spikeis most likely to be affected.

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Figure 8. Inhibition of spiking in the lateral process alters spike half-width in the soma. An experiment with one electrode in the soma of B21 and two electrodes in the lateral process (similar to Fig. 3A) is shown. A1, A2, B21 was peripherally activated and depolarized (bar under bottom trace) so that full-size spikes were triggered in the lateral process. We then hyperpolarized the lateral process (bar under middle trace), which inhibited spiking in the lateral process. Lateral parts of the lateral process were presumably most affected, because potentials at the far lateral site were decreased in amplitude more than potentials at the near lateral site. [Presumably, this is a result of the fact that lateral parts of the lateral process were less depolarized (current was injected into the soma) and were therefore closer to threshold.] Note that the somatic membrane potential remained virtually unchanged. B, C, Peripheral responses 1 and 2 from A at faster sweep speeds. Note that the half-width of the soma spike was decreased when spiking in the lateral process was prevented (most clearly seen in C, which is a superimposition of the soma spikes).

A possible significance of the potentiating effect of the lateral-medial-reflected depolarization is that it could decreasecompartmentalization in B21 when afferent activity is gated-in.For example, it would be reasonable to predict that electrotonicpotentials entering the somatic region of B21 would be decreasedin size by the presence of the lateral process. [This would bepredicted from cable theory (e.g., as a comparison of open-endedvs sealed-end cables). Additionally the input resistance of thecell is presumably decreased by the presence of the lateral process.]Experimentally, we verified this by comparing peripherally generatedsomatic spikes with and without the lateral process. We injectedB21 neurons with fast green dye and then impaled somata with acurrent passing and recording electrode. We triggered activityperipherally and measured spike amplitude at different membranepotentials. We then removed electrodes and severed the connectionbetween the soma and the lateral process. We reimpaled somataand found that in six of seven preparations, afferent spikes recordedat resting membrane potential were larger after the lateral processwas severed (Fig. 9). Thus, the presence of the lateral processtends to decrease the size of entering electrotonic potentials.Interestingly, however, we found that as cells were depolarized,spike amplitude with the lateral process present increased morethan spike amplitude without the lateral process, so that spikesgenerated with the lateral process were not statistically differentfrom those without when depolarizations were >15 mV (Fig. 9).Thus, reflections of depolarizations from the lateral processcould contribute to this "compensatory" response and reduce compartmentalizationwhen afferent activity is gated-in.

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Figure 9. Afferent spikes in the soma before and after the lateral process lesions. When neurons were at their resting membrane potential, afferent spikes recorded after the lateral process had been lesioned were larger than spikes recorded before the lateral process was lesioned (two-tailed paired t test; p = 0.01) (a significant result even when a Bonferroni correction for the repeated measures is applied). When neurons were progressively depolarized, spike amplitude increased both with and without the lateral process (two-factor repeated-measures ANOVA; p < 0.001 for membrane potential; p = 0.0027 for membrane potential and lesion status). Note that, although spikes were initially smaller before the lesion, spike amplitude was increased at least as much as it was after the lesion (10, 20, and 30 mV spike amplitudes are not statistically different when a Bonferroni correction is applied). Overall, therefore, the effect of the lesion was not statistically significant (two-factor repeated-measures ANOVA; p = 0.87).

Afferent activity during ingestive motor programs

In a final set of experiments, we sought to determine whether changes in spike initiation could occur in the lateral processduring physiologically characterized motor programs. Motor programswere induced via stimulation of the command-like neuron CBI-2,and in most (six of seven) preparations, B21 did not spike, orit only spiked occasionally before peripheral stimulation wasinitiated. Afferent transmission was not studied in the preparationin which there was a lot of centrally induced activity in B21.However, we did examine it to determine where B21 was receivingsynaptic input (i.e., the lateral process vs the soma). We foundthat some central activity appeared to be initiated in somaticregions of the cell (i.e., spikes and/or excitatory synaptic potentialswere larger in the soma than in the lateral process), and someactivity appeared to be initiated in the lateral process (i.e.,spikes and/or excitatory synaptic potentials were larger in thelateral process than the soma) (Fig. 10). To verify that this wasnot unique to the one somewhat unusual preparation, we examinedthe central activity that we did observe in other preparations.Although there was much less of this activity, in all cases wewere able to find examples of input to both the lateral processand soma.

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Figure 10. Spikes can be initiated in the lateral process during motor programs. A motor program was induced by stimulation of CBI-2. In this preparation, an unusual amount of centrally induced activity was observed in B21. Only the retraction phase of the motor program is shown in its entirety. Left, Current was not injected into B21. Note that spikes are recorded from both the soma and lateral process. Right, To determine whether spikes originated in the soma or lateral process, hyperpolarizing current was injected into the soma. Many spikes were attenuated in the soma but remained full-size in the lateral process, suggesting that they were initiated in the lateral process. Inset, High-speed recording of the region indicated by the arrow. b, Note that, when spikes were full-size in the lateral process and attenuated in the soma, the peak of depolarization in the lateral process preceded the peak of depolarization in the soma. a, Note that the soma also appeared to be receiving synaptic input, and some depolarizing potentials were larger and peaked earlier than corresponding potentials in the lateral process. L, Lateral; S, soma.

Some cycles of motor programs were classified as ingestive, whereas others were classified as egestive (Jing and Weiss, 2001;Morgan et al., 2002). Some cycles of motor programs were not easilyclassified as either egestive or ingestive and have been referredto as intermediate (see Materials and Methods). During some cyclesof motor programs, IPSPs were observed in B21 during retraction(i.e., during the time when B21 was centrally depolarized). TheseIPSPs were particularly apparent during egestive and intermediatecycles of motor programs. The effects of this inhibitory inputon spike transmission will be considered in a separate study.Here, we concentrate on the effects of depolarization on afferenttransmission and specifically study ingestiveactivity.

When B21 was peripherally activated (i.e., a mechanical stimulus was repeatedly applied to the SRT), action potentials wererecorded in the B21 soma during both the protraction and retractionphases of ingestive motor programs (Fig. 11). To determine whetherrhythmic depolarizations were sufficient to affect afferent transmission,we initially recorded from the soma of B21. We measured spikecharacteristics (amplitude and half-width) before motor programswere initiated and during the latter half of the retraction phaseof the motor programs (i.e., when B21 was not receiving inhibitoryinput). In all cases (i.e., in six of six preparations), we observedan increase in both spike amplitude and half-width in soma recordings(Fig. 11A2). Both increases were statistically significant.

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Figure 11. A1, A2, Somatic potentials are altered during the retraction phase of ingestive motor programs. A1, Left, Peripheral activation of B21 before the motor program. Right, A single cycle of a motor program induced by stimulation of CBI-2. B21 was centrally depolarized during the retraction phase of the motor program, but there was very little centrally induced spike activity in B21 (none is visible in the stretch of recording shown). The spikes apparent in the soma were peripherally triggered. A2, Superimposition of A1a and A1b. Note that, when B21 was centrally depolarized, spikes were increased in amplitude and half-width. Both changes were statistically significant (two-tailed paired t test; p = 0.003 for the half-width comparison; p = 0.005 for the amplitude comparison). B1, B2, Increases in the amplitude and half-width of somatic potentials are correlated with changes in spike amplitude in the lateral process. A single cycle of a motor program induced by stimulation of CBI-2 is shown. B1, During the retraction phase of the motor program, B21 was centrally depolarized and spike amplitude increased in the lateral process. B2, Superimposition of soma (bottom traces) and lateral process (top traces) spikes before and during the retraction phase of the motor program. Soma spikes were increased in amplitude and half-width during retraction, and there was a corresponding change in the amplitude of the lateral process recording.

To determine whether changes in somatic potentials were indicative of changes in spike initiation in the lateral process,in three preparations we simultaneously recorded from the lateralprocess and the soma during motor programs. We found that changesin spike amplitude in the two regions were always correlated.As was expected, changes in spike amplitude in the lateral processwere much more dramatic than changes in spike amplitude in thesoma (Fig. 11B2). On average, we observed a 222 ± 136% increasein spike amplitude in the lateral process and a 32 ± 8% increasein spike amplitude in the soma. The variability in the effectof spike amplitude in the lateral process was likely to be attributableto, at least in part, differences in the placement of the electrodes.For example, in one preparation, the increase in spike amplitudein the lateral process was only 25% and we were recording relativelyclose to the soma. In the other two preparations, we were fartherfrom the soma, and the increases were 159 and 483%. In summary,we conclude that motor program-induced changes in membrane potentialare sufficient to affect spike propagation to the lateral processofB21.

  Discussion

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Gating mechanism

The B21 to B8 connection is striking in that afferent activity is not relayed to B8 when B21 is at its resting potential (Rosenet al., 2000) (Fig. 1C1,C2). Our data suggest that this resultsfrom a failure of active spike propagation. Depolarizing potentialsin the lateral process of B21, the primary contact with B8, areonly ~11 mV. Presumably, propagation failure results, at leastin part, from impedance mismatch as activity is relayed from themedial process to the much larger soma (Yau, 1976; Haydon andWinlow, 1982; Altrup and Speckmann, 1984; Weiss et al., 1986;Luscher et al., 1994; Spruston et al., 1995; Antic et al., 2000).When spike propagation in bipolar and unipolar cells has beencompared, it has become apparent that propagation is less reliablewhen cells are bipolar, particularly when somata are large (Luscheret al., 1994). Additionally, however, other factors may contribute.For example, B21 spikes are characterized by an afterhyperpolarization,which could inhibit conduction (Van Essen, 1973). In any case,active spike propagation fails, and potentials decrement as theyspread throughout the lateral process. Potentials decrement tothe point at which they are not likely to produce significantincreases in intracellular calcium (Spruston et al., 1995). Consequently,transmitter release will bereduced.

In contrast, when B21 is centrally depolarized and then peripherally activated, EPSPs are recorded in B8 (Rosen et al., 2000)(Fig. 1C1,C2). Thus, depolarization gates-in afferent input, presumablybecause spikes are now initiated in the lateral process. Thisgates-in afferent input in a graded manner (Fig. 1C2), which mayindicate that other mechanisms for plasticity are also presentat this synapse (e.g., the release process itself may be voltage-sensitive).Under physiological conditions, spike initiation in the lateralprocess is presumably determined by chemical and/or electricalinput to B21. During motor programs, we recorded excitatory potentialsin the soma and lateral process of B21 that were of central origin.Moreover, when B21 was peripherally activated, motor program-induceddepolarizations were sufficient to convert depolarizations inthe lateral process to full-size action potentials. The regulationof afferent transmission from B21 to B8 could therefore be considered"presynaptic" in that afferent transmission is regulated in B21,which is presynaptic to B8. Presynaptic mechanisms for controllingafferent activity have been described in a number of contexts(Clarac and Cattaert, 1996; Mar and Drapeau, 1996; Apps, 1999;Rudomin, 1999; Wachowiak and Cohen, 1999; Cattaert et al., 2001).

If the proposed mechanism is considered presynaptic, it would be a form of presynaptic facilitation. However, presynapticfacilitation is often thought of as a process that alters spike-inducedtransmitter release (Klein, 1995). Spikes are propagated to terminalswithout facilitatory input, but facilitatory input enhances excitation-secretioncoupling. With this arrangement, the input modifying afferenttransmission is necessarily close to the site of transmitter release(as is also often the case in presynaptic inhibition) (Nusbaumet al., 1997). We have not yet identified the sites at which B21receives facilitatory input, but depolarizations are recordedthroughout the cell, indicating that input is not restricted torelease sites. Thus, our results add to a growing body of workthat indicates that spike propagation itself can be altered bysynaptic input (Meyrand et al., 1992; Wall, 1995; Mar and Drapeau,1996; Debanne et al., 1999; Johnston et al., 1999). This typeof control has been referred to as pre-presynaptic (Wall, 1995).A distinction between presynaptic and pre-presynaptic controlmay be important, because different types of regulation can havedifferent functional consequences (Segev, 1990).

Functional considerations of presynaptic phenomena often emphasize the resulting compartmentalization of a cell. For example,the output of one neuronal process can be altered, whereas theoutput of another process remains unchanged (Wall, 1995; Nusbaumet al., 1997; Clarac and Cattaert, 1999; Rudomin, 1999). Compartmentalizationoccurs when a neuron has output branches that are isolated fromone another. Similarly, it might be predicted that the somaticregion of B21 and its lateral process are different compartments,and that changes in spike initiation in the lateral process ofB21 would be relatively inconsequential for somatic parts of thecell. A spike in the lateral process produces changes in membranepotential in the soma that are much more attenuated than the reflectedspikes that exert potentiating actions in other contexts (Baccus,1998; Baccus et al., 2000). During afferent transmission, however,depolarizations reflected "backward" (from the lateral processto the soma) summate with potentials traveling forward (from themedial process to the soma). Reflected potentials produce relativelysmall changes in somatic spikes, but these types of changes canproduce dramatic effects on synaptic transmission in Aplysia inother contexts (Gingrich and Byrne, 1985; Gingrich et al., 1988).Thus, during afferent transmission, changes in spike initiationin the lateral process may exert important effects on the outputof medial parts of B21, despite the unfavorable length constant.Therefore, our data suggest that in cases in which output regionsof cells are not completely isolated, timing may be importantin determining whether an electrical event in one part of thecell impacts another part. This type of consideration will obviouslycomplicate the classification of one part of a cell as a separatecompartment. A region may be a separate compartment under oneset of circumstances but notanother.

Consequences of gating for feeding in Aplysia

During ingestive behavior, B21 is presumably activated during the two antagonistic phases of the motor program. The tissueinnervated by B21 is a muscle (Cropper et al., 1996) that contributesto radula opening (Borovikov et al., 2000). When the SRT contracts,B21 is activated (Borovikov et al., 2000). Thus, we have shownthat B21 is activated during the radula-protraction phase of ingestivemotor programs. Additionally, B21 is a low-threshold mechanoafferentthat is activated when the radula is touched (Rosen et al., 2000).During ingestion, food will presumably activate B21, because theradula will close on food as it retracts. Thus, B21 will presumablybe activated during both the radula-protraction and -retractionphases of ingestive motorprograms.

If mechanoafferent input is transmitted to the radula-closer motor neuron B8 during radula protraction, the nature of thebehavior will be altered. If the radula begins to close duringprotraction, food is pushed out of the buccal cavity. This iswhat occurs during egestive behaviors but not during ingestivebehaviors (Morton and Chiel, 1993a,b). In contrast, if radulamechanoafferent input is transmitted to B8 during radula retraction,ingestive behavior will be enhanced. The radula will close moretightly as it pulls food into the buccal cavity. Thus, selectivetransmission of mechanoafferent input to B8 during radula retractionis likely to be functionally important for ingestivebehaviors.

Although mechanoafferent input does not appear to be transmitted to B8 during the protraction phase of ingestive motor programs,it may be transmitted to another follower, B64. B64 differs fromB8 in that the B21-B64 contact does not appear to be so exclusivelyvia the lateral process (Borovikov et al., 2000). Spike attenuationin the lateral process is therefore likely to be of less relevance.B64 makes inhibitory connections with a number of protractionneurons and excitatory connections with retraction neurons (Hurwitzand Susswein, 1996; Hurwitz et al., 1997; Jing and Weiss, 2001,2002). The activation of B64 is thought to be an important partof protraction-retraction phase transitions. Processes that accelerateB64 activation phase-advance the retraction phase of motor programs(Hurwitz and Susswein, 1996). B21 is particularly sensitive tothe rate of contraction of the SRT (Borovikov et al., 2000). Thus,B21 will be strongly activated when radula opening (protraction)occurs quickly. Under these conditions, mechanoafferent inputto B64 may be important for producing a corresponding phase advanceof radula retraction. We have demonstrated that stimulation ofB21 with brief current pulses decreases the duration of the protractionphase of CBI-2-induced motor programs (Borovikov et al., 2000).

In conclusion, during the protraction phase of ingestive activity, B21 is presumably functionally compartmentalized in thatafferent activity is transmitted, at least to some degree, tothe retraction interneuron B64, whereas it is not transmittedto the radula-closer motor neuron B8. At least in part, this islikely attributable to the fact that spike initiation in the lateralprocess fails, and electrotonic spikes are too small to inducetransmitter release. Although spikes are also likely to be attenuatedin medial parts of B21 (e.g., the soma), the attenuation is muchless; in addition, the connection with B64 is electrical, andtherefore presumably less dependent on the occurrence of full-sizespikes.

During the retraction phase of ingestive motor programs, B21 is centrally depolarized, and spike initiation will occur inthe lateral process. This will gate-in afferent input to B8 andcontribute to increases in spike amplitude and half-width in somaticregions of B21. The changes in somatic spikes are likely to enhancemechanoafferent input to B64, which will, in turn, enhance retraction.Enhancements of both radula closing and retraction are likelyto be important when food is ingested. Enhanced retraction willensure that the radula moves deeply into the buccal cavity todeposit food in the esophagus. Enhanced closing will ensure thatfood is grasped tightly as it isinternalized.

  FOOTNOTES

Received Sept. 30, 2002; revised Jan. 13, 2003; accepted Jan. 14, 2003.

This work was supported by National Institutes of Health (NIH) K02 Award MH01267 and United States Public Health Service GrantsMH51393 and MH35564. The National Resource for Aplysia of theUniversity of Miami provided some of the Aplysia used in thisstudy under National Center for Research Resources (NIH) GrantRR-10294. We thank K. R. Weiss and V. Brezina for valuable commentson a previous version of thismanuscript.

Correspondence should be addressed to E. C. Cropper, Department of Physiology and Biophysics, P.O. Box 1218, Mount Sinai Schoolof Medicine, 1 Gustave L. Levy Place, New York, NY 10029. E-mail:elizabeth.cropper{at}mssm.edu.

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Materials and Methods
Results
Discussion
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