Motor Pattern Selection via Inhibition of Parallel Pathways

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Volume 17, Number 13, Issue of July 1, 1997 pp. 4965-4975
Copyright ©1997 Society for Neuroscience

Motor Pattern Selection via Inhibition of Parallel Pathways

Dawn M. Blitz and Michael P. Nusbaum
Department of Neuroscience, University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Motor pattern selection from a multifunctional neural network often results from direct synaptic and modulatory actions ofdifferent projection neurons onto neural network components. Lesswell documented is the presence and function of interactions amongdistinct projection neurons innervating the same network. In thestomatogastric nervous system of the crab Cancer borealis, severaldistinct projection neurons that influence the pyloric and gastricmill rhythms have been studied. These rhythms are generated byoverlapping subsets of identified neurons in the stomatogastricganglion (STG). One of these identified projection neurons isthe modulatory proctolin neuron (MPN). We showed previously thatMPN stimulation excites the pyloric rhythm by its excitatory actionson STG neurons. In contrast to its excitatory actions on the pyloricrhythm, we have now found that MPN inhibits the gastric mill rhythm.This inhibition does not occur within the STG, but instead resultsfrom MPN-mediated inhibition of two previously identified projectionneurons within the commissural ganglia. These projection neuronsinnervate the STG and, via their actions on STG neurons, theyelicit the gastric mill rhythm as well as modify the pyloric rhythmin a manner distinct from MPN. By inhibiting these projectionneurons, MPN removes excitatory drive to gastric mill neuronsand elicits an MPN-specific pyloric rhythm. Motor pattern selectionby MPN therefore results from both a direct modulation of STGnetwork activity and an inhibition of competing pathways.
Key words: stomatogastric nervous system; crustacea; projection neurons; neuromodulation; Cancer borealis

INTRODUCTION

Neuromodulatory inputs enable rhythmically active neural networks to produce multiple distinct motor patterns (Harris-Warrickand Marder, 1991; Soffe, 1993; Dickinson, 1995; Katz, 1995; Kiehnand Kjærulff, 1996; Marder and Calabrese, 1996). These networksare often influenced by sets of distinct modulatory neurons (Weeksand Kristan, 1978; Brodfuehrer and Friesen, 1986; Nusbaum andKristan, 1986; Rosen et al., 1991; Rossignol and Dubuc, 1994;Grillner et al., 1995; Marder et al., 1995; Thorogood and Brodfuehrer,1995). However, little information is available regarding whetherdistinct inputs to any single network act exclusively as independentparallel pathways or whether they also interact with one another(Brodfuehrer and Burns, 1995; Faumont et al., 1996).

This issue can be studied effectively in the stomatogastric nervous system (STNS) of decapod crustacea (Harris-Warrick etal., 1992a; Marder and Weimann, 1992). The STNS consists of thestomatogastric ganglion (STG), the esophageal ganglion (OG), andthe paired commissural ganglia (CoGs). In the crab Cancer borealis,overlapping subsets of STG neurons generate the gastric mill andpyloric rhythms (Weimann et al., 1991; Weimann and Marder, 1994).These rhythms control chewing and the movement of chewed foodfrom the foregut to the midgut, respectively (Johnson and Hooper,1992). Different versions of these two rhythms are elicited bysuperfusion of different neuromodulators (Harris-Warrick et al.,1992b; Marder and Weimann, 1992; Weimann et al., 1993; Skiebeand Schneider, 1994; Blitz et al., 1995) and by activation ofdifferent sensory and projection neurons (Nusbaum and Marder,1989a,b; Katz and Harris-Warrick, 1991; Coleman and Nusbaum, 1994;Norris et al., 1994a, 1996; Blitz and Nusbaum, 1996; Bartos andNusbaum, 1997).

One identified projection neuron in the crab STNS is the modulatory proctolin neuron (MPN) (Nusbaum and Marder, 1989a,b).MPN projects from the OG to the STG and both CoGs. The modulatoryeffects of MPN activity on pyloric circuit neurons in the STGresult in a pyloric rhythm that is comparable to that resultingfrom superfusion of the neuropeptide proctolin. Nusbaum and Marder(1989a,b) did not study the MPN influence on the gastric millrhythm, because all CoG inputs were eliminated in their experiments,and in C. borealis, this rhythm depends on input from CoG projectionneurons (Coleman and Nusbaum, 1994; Norris et al., 1994a).

Here, we show that MPN stimulation inhibits the gastric mill rhythm. However, MPN does not directly inhibit any STG neurons.Instead, MPN inhibits two identified CoG projection neurons, theactivity of which elicits gastric mill rhythms. These CoG neuronsare modulatory commissural neuron 1 (MCN1) (Coleman and Nusbaum,1994; Coleman et al., 1995) and commissural projection neuron2 (CPN2) (Norris et al., 1994a). MPN activity also enhances orevokes pyloric-timed activity in many gastric mill neurons viaits modulatory actions in the STG. Thus, via its combined excitatoryactions on STG network neurons and its inhibitory actions on CoGprojection neurons, MPN activity biases the STG network to producea specific pyloric rhythm in the absence of the gastric mill rhythm.Some of this work has appeared previously in abstract form (Blitzand Nusbaum, 1994).

MATERIALS AND METHODS
Animals. Crabs, Cancer borealis, were obtained from commercial suppliers (Boston, MA) and from the Marine Biological Laboratory(Woods Hole, MA). Crabs were maintained in aerated artificialseawater at 10-12°C. Immediately before dissection, crabs werecold anesthetized by packing in ice for 20-40 min. The foregut,including the STNS, was removed and pinned in a silicone elastomer(SYLGARD 170, Dow Corning, Midlands, MI)-lined bowl filled withchilled (~4°C) physiological saline. The STNS was then dissectedfree from the foregut. Data were obtained from 95 male crabs.

Solutions. C. borealis physiological saline had the following composition (in mM): NaCl 440, MgCl₂ 26, CaCl₂ 13, KCl 11, Trismabase 10, maleic acid 5, pH 7.4-7.6. Low Ca²⁺ saline had the following composition (in mM): NaCl 440, MgCl₂26, CaCl₂ 1.3, KCl 11, MnCl₂ 11.7, Trisma base 10, maleic acid5, pH 7.4-7.6. Saline of this composition blocks transmitter releasein the crab STNS (Coleman, 1995; Coleman et al., 1995). F₁ peptide(TNRNFLRFamide) was obtained from Peninsula (Belmont, CA). Oxotremorinewas obtained from Sigma (St. Louis, MO).

Electrophysiology. Electrophysiological experiments were performed using standard techniques for this system (Selverston andMoulins, 1987; Bartos and Nusbaum, 1997). The isolated STNS (Fig.1) was pinned down in a silicone elastomer- (SYLGARD 184, DowCorning) lined Petri dish. In a few experiments (n = 4), a semi-intactpreparation was used in which some STG motor nerves innervatedtheir target pyloric and/or gastric mill muscles. For these preparations,the posterior stomach wall and associated muscles along with theSTNS were pinned down in a SYLGARD-lined Petri dish. All preparationswere superfused continuously at 7-12 ml/min with crab physiologicalsaline (10°-13°C). Intracellular and extracellular recordingswere performed as reported previously (Bartos and Nusbaum, 1997).Intracellular current injection was performed using Axoclamp 2amplifiers (Axon Instruments, Foster City, CA) in single-electrodediscontinuous current clamp mode. Sample rates during discontinuouscurrent clamp were ~3 KHz. Data were collected on chart recorder(Astro-Med MT-95000) and videotape (Vetter Instruments, Rebersburg,PA).
Fig. 1. Schematics of the STNS, including somata location and axonal pathway of the identified projection neurons MPN, MCN1, and CPN2.A, There is a pair of MPN somata located either in the OG or inthe nerve posterior to this ganglion. Each MPN projects an axonthrough each superior esophageal nerve (son) to the CoG and throughthe stomatogastric nerve (stn) to the STG. It also projects anaxonal branch from each superior esophageal nerve through theperipheral nerve dorsal posterior esophageal nerve (dpon). Forclarity, the complete projection of only one MPN is shown. B,There is a single MCN1 and CPN2 in each CoG. Each MCN1 projectsthrough the inferior esophageal nerve (ion) and stomatogastricnerve to the STG. Each CPN2 projects through the superior esophagealnerve and stomatogastric nerve to the STG. For clarity, the completeprojection of only one MCN1 and one CPN2 is shown. CoG, Commissuralganglion; OG, esophageal ganglion; dgn, dorsal gastric nerve;lgn, lateral gastric nerve; lvn, lateral ventricular nerve; mvn,medial ventricular nerve; pdn, pyloric dilator nerve; CPN2, commissuralprojection neuron 2; MCN1, modulatory commissural neuron 1; MPN,modulatory proctolin neuron. Anterior is toward the top of thefigure and posterior is toward the bottom.
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In some experiments, the anterior portion of the STNS (CoGs and OG) was superfused separately from the STG so that it couldbe superfused selectively with low Ca²⁺ saline via a switching manifold. To this end, the two compartmentswere separated by building a petroleum jelly wall across the recordingdish. Gastric mill rhythms were spontaneous or elicited in somepreparations by superfusing a combination of the neuropeptideF₁ (10⁷ M) and the muscarinic agonist oxotremorine (10⁷-10⁵ M) to the entire preparation (Weimann et al., 1993). All resultswere the same for spontaneous and transmitter-elicited gastricmill rhythms. Therefore, these data were pooled. In one seriesof control experiments, gastric mill rhythms were elicited byselective activation of MCN1 via extracellular stimulation ofthe inferior esophageal nerve (ion15-20 Hz) (Coleman, 1995; Colemanet al., 1995). The ion was stimulated using a Grass S88 stimulatorand Grass SIU5 stimulus isolation unit (Astro-Med/Grass Instruments,Quincy, MA). Throughout the paper, the phrases pyloric-timed andgastric mill-timed indicate activity that is time-locked to thepyloric- or gastric mill rhythm, respectively.

Individual STG neurons were identified electrophysiologically by documenting the activity pattern and axon projection patternof each neuron as well as its synaptic interactions with otheridentified neurons (Weimann et al., 1991; Coleman and Nusbaum,1994; Norris et al., 1994a, 1996; Coleman et al., 1995; Bartosand Nusbaum, 1997). The mean number of spikes per pyloric-timedburst in individual STG neurons was determined by calculatingthe mean number of spikes per burst from 10 consecutive cyclesbefore and during MPN stimulation.

Figures were made by scanning data with an HP ScanJetIIC, using DeskScan II (version 2.00a) software. Final figures were producedusing CorelDraw (Version 3.0 for Windows). Paired Student's ttest, performed with SigmaPlot for Windows (Version 1.02), wasused to determine statistical significance. Data are expressedas mean ± SD.

RESULTS

MPN inhibits the gastric mill rhythm
The gastric mill rhythm produces alternating protraction and retraction movements of the paired lateral teeth and the singlemedial tooth in the gastric mill region of the crustacean stomach(Heinzel et al., 1993). In the isolated crab STNS, the gastricmill rhythm has a characteristic period that ranges between 8and 15 sec (Norris et al., 1994a). The crab STG produces severalforms of the gastric mill rhythm, both in vitro (Coleman et al.,1993; Weimann et al., 1993; Coleman and Nusbaum, 1994; Norriset al., 1994a) and in vivo (Powers, 1973; Heinzel et al., 1993).

Examples of the two most common versions of the gastric mill rhythm recorded in vitro in C. borealis are shown in Figure 2.One standard characteristic of these two gastric mill rhythmsis the alternating bursting of the lateral gastric (LG, lateralteeth protractor) and dorsal gastric (DG, medial tooth retractor)motor neurons. The gastric mill rhythm shown in Figure 2A is alsocharacterized by inhibition of the ventricular dilator (VD) neuron(mvn) during each LG burst and weak or absent gastric mill (GM)neuron (dgn, smallest unit) activity. This gastric mill rhythmis elicited by selective activation of the CoG projection neuronMCN1 (Fig. 1B) (Nusbaum et al., 1992; Coleman and Nusbaum, 1994;Coleman et al., 1995). Furthermore, when this rhythm is elicitedby application of neuromodulators to the STNS or results fromspontaneous activity, MCN1 activity is always evident in extracellularrecordings of the ion (Coleman and Nusbaum, 1994). Finally, suppressingMCN1 activity eliminates this rhythm (Coleman, 1995). Thus, inthis paper, we have designated this version of the gastric millrhythm the MCN1-elicited gastric mill rhythm.
Fig. 2. Examples of gastric mill rhythms elicited by MCN1 alone and by conjoint activity in MCN1 and CPN2. A, Left, Extracellularrecordings of STG motor nerves during an MCN1-elicited gastricmill rhythm (mvn, dgn, lgn) and pyloric rhythm (pdn). This gastricmill rhythm is characterized by rhythmic alternating burstingin the LG (lgn) and DG (dgn) neurons. The VD neuron (smaller unitin the mvn) is silent during each LG burst, and IC (larger unitin the mvn) is silent during each DG burst. Right, Schematic ofthe time of activity of STG neurons during an MCN1-elicited gastricmill rhythm. This gastric mill rhythm was elicited by selectivestimulation of MCN1 (see also Coleman and Nusbaum, 1994; Colemanet al., 1995). B, Left, Extracellular recordings monitoring thepyloric and gastric mill rhythms during coactivation of MCN1 andCPN2. This gastric mill rhythm differs in several ways from therhythm elicited by selective activation of MCN1. The cycle periodis longer, both IC and VD (mvn) are completely inhibited duringeach LG burst, and the GM neurons (smallest unit in dgn) are stronglyactivated during each LG burst (see also Norris et al., 1994a).Right, Schematic of the time of activity of STG neurons duringan MCN1/CPN2-elicited gastric mill rhythm. In this recording,MCN1 and CPN2 were activated by bath application of 10⁵ M oxotremorine to the entire preparation. The tonically activeunit in the dgn in these and all subsequent dgn recordings isthe anterior gastric receptor sensory neuron. Dark cell bodiesrepresent active neurons; light cell bodies represent inactiveneurons.
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The gastric mill rhythm shown in Figure 2B has several features that distinguish it from the MCN1-elicited rhythm. For example,the cycle period is generally longer, and each LG burst is moreintense (Norris et al., 1994a). Additionally, overlapping witheach LG burst is intense GM neuron (dgn) bursting and inhibitionof both the inferior cardiac (IC) and VD neurons (mvn). Simultaneousactivation of two CoG projection neurons, MCN1 and CPN2 (Fig.1B), elicits this rhythm (Norris et al., 1994a) (see below). Thus,this rhythm has been designated the MCN1/CPN2-elicited gastricmill rhythm.

Intracellular stimulation of MPN consistently inhibited these two gastric mill rhythms. As is evident in Figure 3A, MPN stimulationinhibited ongoing MCN1-elicited gastric mill rhythms (n = 13 preparations).Accordingly, during these MPN stimulations, the gastric mill-timedbursts in the LG and DG neurons were suppressed. Note that theMPN stimulation also enhanced the ongoing pyloric rhythm (Fig.3A, mvn). This excitation of the pyloric rhythm results from MPNexcitation of the pyloric neurons in the STG (Nusbaum and Marder,1989b). The suppression of the gastric mill rhythm often persistedfor >10 sec after MPN stimulation was terminated, after whichthere was a gradual buildup in rhythmic activity before the rhythmreturned to prestimulus levels.
Fig. 3. MPN activity inhibits the gastric mill rhythm. A, An ongoing MCN1-elicited gastric mill rhythm is suppressed by intracellularstimulation of MPN (firing frequency, 13 Hz). This resulted intermination of activity in the LG and DG neurons and the eliminationof gastric mill-timed inhibition of the VD and IC neurons. Thegastric mill rhythm resumed 10 sec after the end of the MPN stimulation.B, An MCN1/CPN2-elicited gastric mill rhythm was evoked by bathapplication of 10⁶ M oxotremorine and 10⁷ M F₁ peptide to the entire preparation. This rhythm was suppressedby MPN stimulation (firing frequency, 11 Hz), resulting in immediatetermination of activity in the LG and GM neurons and the eliminationof the gastric mill-timed inhibition in the mvn. Shortly thereafter,DG neuron activity also terminated. The gastric mill rhythm resumed11 sec after the end of the MPN stimulation. MPN resting potentialswere $-$ 58 mV (A) and $-$ 62 mV (B). The recordings in A and B arefrom different preparations.
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Similarly, intracellular stimulation of MPN reversibly inhibited MCN1/CPN2-elicited gastric mill rhythms (n = 10 preparations).As was the case for MCN1-elicited gastric mill rhythms, MPN stimulationcaused a long-lasting elimination of all gastric mill-timed activityand enhanced the ongoing pyloric rhythm (Fig. 3B). These gastricmill rhythms typically resumed within 20 sec after MPN stimulationwas terminated.

MPN projects axons to the CoGs and STG (Nusbaum and Marder, 1989a) (Fig. 1A). Therefore, its inhibition of the gastric millrhythm could have occurred in the STG via inhibition of gastricmill circuit neurons and/or the STG terminals of MCN1 and CPN2.The STG terminals of projection neurons are known to receive synapticinput from STG circuit neurons (Nusbaum et al., 1992; Colemanand Nusbaum, 1994). Alternatively, the MPN inhibition of the gastricmill rhythm could have occurred via an inhibition of MCN1 andCPN2 in the CoGs. We examined the influence of MPN activity inthe STG and CoGs and found that MPN influenced the activity ofgastric mill circuit neurons via its actions in both locations.

MPN effects in the STG
Several STG neurons in the crab participate in both the pyloric and the gastric mill rhythms. These include the IC, VD, andmedial gastric (MG) motor neurons plus interneuron 1 (Int1) (Weimannet al., 1991; Norris et al., 1994a; Weimann and Marder, 1994).Nusbaum and Marder (1989b) showed that MPN stimulation increasedthe pyloric-timed activity of the IC neuron when activity in theCoGs was suppressed. We found that when the CoGs remained connectedto the STG, MPN stimulation increased the pyloric-timed activityof all four of these gastro-pyloric neurons, regardless of whetherthe gastric mill rhythm was in progress. The effects of MPN onthese neurons consisted of an increase in the depolarized amplitudeof their pyloric-timed membrane potential oscillations (Fig. 4)as well as an increase in the number of action potentials perburst fired by each neuron (Fig. 4; Table 1). These effects tendedto outlast the period of MPN stimulation by several tens of seconds.
Fig. 4. MPN increases the pyloric-timed activity of some STG gastro-pyloric neurons. A, During a time when there was an ongoing pyloricrhythm in the absence of a gastric mill rhythm, MPN stimulation(firing frequency, 13 Hz) excited the pyloric rhythm (mvn) andincreased the pyloric-timed activity of Int1, VD, and IC. Thisis evident from the increased number of action potentials firedper pyloric-timed burst in each of these neurons. MPN stimulationalso caused an increase in the amplitude of the depolarized phaseof the membrane potential oscillations of each neuron, as is evidenthere for Int1 and in B for MG. These effects outlasted the stimulationand returned to baseline after 30 sec. B, MPN stimulation (firingfrequency, 18 Hz) evoked pyloric-timed impulse activity in MG.MG began to fire action potentials that were time-locked to thepyloric rhythm during the MPN stimulation. This activity levelreturned to baseline after 48 sec. MPN stimulation also increasedthe amplitude of the membrane potential oscillations of MG. Mosthyperpolarized membrane potentials: (A) Int1, $-$ 71 mV; MPN, $-$ 51mV; (B) MG, $-$ 61 mV; MPN, $-$ 49 mV.
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Table 1. Effects of MPN stimulation on STG gastro-pyloric neurons

Neuron ^# Spikes/pyloric rhythm-timed burst

Control MPN stimulation n

IC 1.1 ± 0.9 3.3 ± 1.2^** 23

VD 1.5 ± 1.4 2.4 ± 1.5^** 21

Int1 3.5 ± 3.1 5.7 ± 3.2^** 11

MG 0.6 ± 0.7 2.3 ± 2.1^** 11

^** p $<=$ 0.01 (paired Student's t test)

In the absence of the gastric mill rhythm, the DG neuron is often silent in the isolated crab STNS. MPN stimulation had variableeffects on DG neuron activity. DG activity was slightly enhanced(n = 7/21 preparations), inhibited (n = 9/21), or not altered(n = 5/21). DG rarely exhibits pyloric-timed activity in vitro(Weimann et al., 1991), and MPN stimulation did not elicit eitherpyloric-timed activity (n = 21 preparations) or subthreshold oscillationsin this neuron (n = 8 preparations). The variable effects of MPNon DG appear to be a consequence of MPN inhibition of other projectionneurons that influence DG (see below).

Two additional gastric mill neurons, GM and LG, exhibit intermittent pyloric-timed slow wave oscillations and spikes. MPNstimulation increased the pyloric-timed inhibition to these neuronsand did not enhance their activity. Instead, MPN stimulation decreasedGM neuron activity (n = 12/14 preparations) (Fig. 5) and increasedthe pyloric-timed hyperpolarizations of its membrane potential(n = 30/32 preparations) (Fig. 5). Similarly, when LG was firingaction potentials, MPN stimulation decreased LG activity (n =13/16 preparations) and increased the amplitude of its pyloric-timedmembrane potential hyperpolarizations (n = 33/34 preparations)(see below).
Fig. 5. MPN excitation of the IC neuron elicits subthreshold pyloric-timed inhibition in the GM neuron. Left, MPN stimulation (firingfrequency, 10 Hz) excited the IC and VD neurons and evoked pyloric-timedinhibition in GM. During MPN stimulation, there was also an eliminationof the action potentials and tonically occurring EPSPs in GM.Right, When the IC membrane potential was hyperpolarized via DCcurrent injection, MPN stimulation (firing frequency, 10 Hz) stillexcited the pyloric rhythm, but it no longer evoked pyloric-timedinhibition in GM. However, the action potentials and tonic EPSPsin GM were still eliminated. Note that when IC was hyperpolarized,its response to MPN stimulation resulted in an activity levelthat was slightly weaker than that occurring before MPN stimulationin the absence of hyperpolarizing current injection. Most hyperpolarizedmembrane potentials: (A) GM, $-$ 50 mV; IC, $-$ 58 mV; MPN, $-$ 70 mV;(B) GM, $-$ 54 mV; IC, $-$ 70 mV; MPN, $-$ 70 mV.
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It was possible that the MPN-elicited increases in the pyloric-timed inhibition in these two gastro-pyloric neurons resultedfrom MPN excitation of other STG neurons. In six of six preparationsin which GM was exhibiting pyloric-timed hyperpolarizations, MPNstimulation increased the amplitude of these hyperpolarizations.In 26 other preparations, GM did not exhibit these hyperpolarizationsduring saline superfusion. However, in 24 of these 26 preparations,MPN stimulation elicited pyloric-timed hyperpolarizations in GM.When IC neuron activity is strong, it provides inhibitory inputto GM (Weimann, 1992), and IC activity is enhanced significantlyby MPN stimulation (Nusbaum and Marder, 1989b; present study).We examined whether the MPN effects on GM occurred via MPN excitationof IC by stimulating MPN while reducing IC activity with hyperpolarizingcurrent injection (Fig. 5). With IC activity reduced, MPN stimulationdid not elicit these pyloric-timed events in GM (n = 11 preparations).

The LG neuron receives pyloric-timed inhibitory input from two sources, Int1 (Norris et al., 1994a) and the pyloric pacemakerensemble (D. Blitz, M. Nusbaum, unpublished observations). Theincreased activity of these neurons during MPN stimulation (Int1,Fig. 4, Table 1; pyloric pacemaker ensemble, Nusbaum and Marder,1989a) is responsible for the pyloric-timed hyperpolarizationsin the LG membrane potential (data not shown).

In addition to the pyloric-timed effects of MPN on GM and LG, MPN stimulation consistently eliminated spontaneously occurringEPSPs in GM (Fig. 5; n = 32 preparations) and LG (see below) (n= 37 preparations) that were not related to the pyloric rhythm.These EPSPs result entirely from spontaneous activity in the projectionneurons MCN1 and CPN2 (Coleman and Nusbaum, 1994; Norris et al.,1994a). Our data therefore suggested that MPN activation eliminatedthe EPSPs in LG and GM and inhibited the gastric mill rhythm byinhibiting MCN1 and CPN2.

MPN effects in the CoGs
If MPN did indeed inhibit MCN1 and CPN2 and thereby inhibit the gastric mill rhythm, then it might have done so within theCoGs, at their terminals within the STG, or at both locations.We first examined whether the inhibitory effects of MPN occurredin the CoGs. To this end, we selectively superfused the CoGs andOG with low Ca²⁺ saline (see Materials and Methods) to suppress transmitter release.This saline often initiated or increased spontaneous activityin CoG neurons and elicited a gastric mill rhythm from the STG.The increased activity in CoG neurons may result from an eliminationof the inhibitory synaptic effects of spontaneously active neuronsin the CoGs.

As in our previous experiments, before we suppressed transmitter release in the CoGs, MPN stimulation inhibited the gastricmill rhythm (Fig. 6A). In contrast, when transmitter release inthe CoGs was suppressed, MPN stimulation no longer inhibited thegastric mill rhythm (Fig. 6B; n = 5 preparations). Nonetheless,under the latter condition, MPN still effectively excited thepyloric rhythm in the STG, which was continually superfused withnormal saline (see below).
Fig. 6. MPN does not inhibit the gastric mill rhythm when transmitter release is suppressed in the CoGs. A, When the CoGs were superfusedwith normal saline, MPN stimulation (firing frequency, 17 Hz)inhibited the gastric mill rhythm, as evident by the eliminationof LG and DG bursting. B, When transmitter release was suppressedin the CoGs by superfusion with low Ca²⁺ saline, MPN stimulation (firing frequency, 17 Hz) had no effecton the gastric mill rhythm. Most hyperpolarized membrane potentials:LG, $-$ 72 mV; MPN, $-$ 50 mV. Calibration applies to both A and B.
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It was possible that MPN was inhibiting MCN1 and CPN2 in the CoGs and thereby removing excitation to the gastric mill system.Alternatively, MPN might have been exciting a CoG neuron(s) thatprojected to the STG and inhibited the gastric mill rhythm. IfMPN was indeed inhibiting the gastric mill rhythm not by inhibitingMCN1 and CPN2 in the CoG, but by exciting a CoG neuron that projectedto the STG, then MPN should be able to suppress this rhythm regardlessof where MCN1 was activated. To test this latter possibility,we examined whether MPN stimulation could inhibit the gastricmill rhythm when this rhythm was elicited by activating MCN1 ata site outside of the CoG. This would circumvent any possibleinhibitory influence in the CoG of MPN on MCN1 activity. Thus,we elicited the gastric mill rhythm by selectively activatingMCN1 via extracellular stimulation of the ion (Coleman et al.,1995). We found that MPN stimulation did not inhibit gastric millrhythms elicited by ion stimulation (n = 6 preparations). Consequently,we focused on determining whether the MPN inhibition of the gastricmill rhythm resulted from its having inhibitory actions on MCN1and CPN2 in the CoGs.

MPN stimulation did indeed inhibit both MCN1 and CPN2 in the CoGs (Fig. 7). Activity in both of these projection neurons waseither reduced or terminated by MPN stimulation (n = 42 preparations).Accompanying this inhibition, these neurons exhibited a slow hyperpolarizationthat often outlasted the MPN stimulation by several seconds. DiscreteIPSPs time-locked to each MPN action potential were not evidentin either MCN1 or CPN2. MPN inhibition of these neurons, however,was often accompanied by a barrage of depolarizing postsynapticpotentials that were not time-locked to the MPN action potentials.
Fig. 7. MPN activity inhibits MCN1 and CPN2 in the CoGs. A, Left, Intracellular recordings of LG in the STG, MCN1 in the CoG and MPNin the esophageal nerve, posterior to the OG. LG is not firingaction potentials but is receiving EPSPs from MCN1 and CPN2. Thelarge-amplitude EPSPs represent input to LG from MCN1, and theyare time-locked to the MCN1 action potentials. MCN1 is spontaneouslyactive. LG is also receiving smaller amplitude EPSPs from CPN2(see B). MPN stimulation (firing frequency, 11 Hz) inhibited MCN1,causing a cessation of MCN1 activity and hyperpolarization ofits membrane potential. This eliminated all of the EPSPs in LG.Note also that the MPN stimulation excited the pyloric rhythm(mvn). Right, Schematic diagram indicating MPN inhibition of MCN1,removing excitatory input to LG. Dark cell bodies represent activeneurons; light cell bodies indicate inactive neurons. Small, solidcircles indicate transmitter-mediated synaptic inhibition; T-barsindicate an excitatory synapse. B, Left, Intracellular recordingsof GM in the STG, CPN2 in the CoG and MPN in the esophageal nerve.GM is not firing action potentials but is receiving EPSPs fromboth CPN2 neurons, which are spontaneously active. MPN stimulation(firing frequency, 17 Hz) inhibited both the recorded CPN2 andits contralateral homolog, as is evident by the (1) cessationof CPN2 activity, (2) associated hyperpolarization of the CPN2membrane potential, and (3) elimination of the EPSPs that GM wasreceiving. The MPN stimulation also excited the pyloric rhythm(mvn). Right, Schematic diagram indicating that MPN inhibits CPN2,removing excitatory input to GM and LG (symbols as in A). Mosthyperpolarized membrane potentials: (A) LG, $-$ 44 mV; MCN1, $-$ 66mV; MPN, $-$ 56 mV; (B) GM, $-$ 64 mV; CPN2, $-$ 56 mV; MPN, $-$ 65 mV.
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Note that at the same time that MPN activity inhibited MCN1 and CPN2 in the CoG, it was exciting the pyloric rhythm in theSTG (Figs. 7A,B). Concurrently, the MCN1-elicited EPSPs in LGwere eliminated (Fig. 7A). MCN1 action potentials elicit relativelylarge-amplitude monosynaptic electrical EPSPs in LG (Fig. 7A)(Coleman et al., 1995). CPN2 action potentials elicit smalleramplitude, fixed-latency EPSPs in LG as well as in GM (Norriset al., 1994a). In the isolated STNS of C. borealis, all spontaneouslyoccurring EPSPs in GM originate from CPN2 activity (Norris etal., 1994a; D. Blitz and M. Nusbaum, unpublished observations).Regardless of whether MCN1 was spontaneously active, LG and GMoften received a tonic barrage of EPSPs from CPN2, and these EPSPswere consistently eliminated coincident with the MPN-mediatedinhibition of CPN2 activity (Fig. 7B).

To confirm that the low Ca²⁺ saline superfusion of the CoGs and OG that we used to suppress MPN inhibition of the gastric millrhythm was also sufficient to suppress its inhibition of MCN1and CPN2, we again selectively superfused these ganglia with lowCa²⁺ saline. Under this condition, MPN stimulation no longer influencedeither MCN1 (Fig. 8A; n = 7 preparations) or CPN2 (Fig. 8B; n= 9 preparations). In addition, MPN neither reduced nor eliminatedthe EPSPs in LG and GM, nor did it influence any other effectsof MCN1 and CPN2 within the STG. Note that during these times,MPN stimulation continued to excite the pyloric rhythm in theSTG (Fig. 8). These results support the hypothesis that the MPN-mediatedinhibition of these projection neurons in the CoG is responsiblefor the MPN-mediated inhibition of the gastric mill rhythm inthe STG. It also suggested that there was no functionally importantinfluence of MPN on the STG terminals of these projection neurons.The effect of low Ca²⁺ saline was readily reversible.
Fig. 8. MPN activity does not inhibit MCN1 or CPN2 when transmitter release in the CoGs is suppressed. A, Left, MPN stimulation (firingfrequency, 14 Hz) inhibited MCN1, thereby terminating MCN1 activityand causing a hyperpolarization of the MCN1 membrane potential.Note that MPN stimulation excited the pyloric rhythm (mvn). Right,When the CoGs were selectively superfused with low Ca²⁺ saline to suppress transmitter release, MPN stimulation had noeffect on MCN1. During this time, the STG was superfused withnormal saline, and consequently MPN stimulation still excitedthe pyloric rhythm. B, Left, MPN stimulation (firing frequency,19 Hz) inhibited CPN2, causing CPN2 to hyperpolarize and stopfiring action potentials. Right, With transmitter release suppressedin the CoGs, MPN stimulation had no effect on CPN2. Most hyperpolarizedmembrane potentials: (A) MCN1, $-$ 65 mV; MPN, $-$ 75 mV; (B) CPN2, $-$ 63 mV; MPN, $-$ 56 mV. The recordings in A and B are from differentpreparations.
[View Larger Version of this Image (65K GIF file)]

We also examined the influence of MPN on MCN1 and CPN2 during gastric mill rhythms to document that MPN did indeed inhibitthese projection neurons during times when it inhibited the gastricmill rhythm. In all preparations studied, we found that MPN stimulationinhibited both MCN1-elicited (n = 7) and MCN1/CPN2-elicited (n= 7) gastric mill rhythms coincident with its inhibition of theseprojection neurons (Fig. 9). Furthermore, the resumption of thesegastric mill rhythms after MPN stimulation coincided with thereturn of MCN1 and CPN2 activity to prestimulus levels. Note,in Figure 9, that MPN stimulation terminated activity in bothMCN1 and CPN2 for the duration of MPN activity (6 sec). It thentook ~1 min longer before the activity level of these projectionneurons was again sufficiently strong to drive the gastric millrhythm.
Fig. 9. During an ongoing MCN1/CPN2-elicited gastric mill rhythm, MPN stimulation inhibits MCN1, CPN2, and the gastric mill rhythm.The gastric mill rhythm is represented here by the rhythmic inhibitionof IC and VD (mvn) and the rhythmic bursting of the GM neuron.MCN1 and CPN2 are both firing high-frequency bursts of actionpotentials, and both are participating in the production of thisgastric mill rhythm. CPN2 activity is monitored by an intra-axonalrecording of its stomatogastric nerve axon (SNAX). MPN stimulation(firing frequency, 16 Hz) inhibited MCN1, CPN2, and the gastricmill rhythm. After MPN stimulation, MCN1 and CPN2 activity levelsgradually returned to prestimulus levels, at which time the gastricmill rhythm resumed. This occurred ~1 min after the end of theMPN stimulation. Most hyperpolarized membrane potentials: CPN2_SNAX, $-$ 66 mV; GM, $-$ 52 mV; MPN, $-$ 82 mV.
[View Larger Version of this Image (65K GIF file)]

Also noteworthy in Figure 9 is that there was no indication of MPN-mediated synaptic inhibition in the CPN2_SNAX recording.The stomatogastric nerve axon (SNAX) recording is an intra-axonalrecording of CPN2 at the entrance to the STG. Synaptic eventsoccurring at the STG terminals of projection neurons are readilyrecorded at this site (Nusbaum et al., 1992; Coleman and Nusbaum,1994). In contrast, the SNAX recording site is electrotonicallyremote from the CoG (Coleman and Nusbaum, 1994). When MPN stimulationeliminated the CPN2 action potentials, which had been propagatingtoward the STG from the CoG, the only synaptic events evidentin CPN2_SNAX were pyloric-timed membrane potential oscillations(Fig. 9). These oscillations result from pyloric-timed synapticinput to CPN2 in the STG (D. Blitz and M. Nusbaum, unpublishedobservations).

DISCUSSION

Motor pattern selection
Our results indicate that the modulatory projection neuron MPN elicits a specific motor pattern from the STG network via bothdirect and indirect effects. Its excitatory actions in the STGenable MPN to elicit a pyloric rhythm that is comparable to therhythm elicited by proctolin superfusion (Nusbaum and Marder,1989b). We showed here that these MPN actions also include enhancingthe pyloric-timed activity of some gastric mill neurons in theSTG. At the same time, via its inhibitory effects on projectionneurons in the CoGs, MPN inhibits the expression of the gastricmill rhythm in the STG (Fig. 10). These inhibitory actions includethe MPN-mediated inhibition of MCN1 and CPN2, two projection neuronsidentified previously, the activity of which is instrumental inthe production of gastric mill rhythms (Coleman and Nusbaum, 1994;Norris et al., 1994a; Coleman et al., 1995). At least two otherCoG projection neurons, MCN5 and MCN7, elicit different versionsof the gastric mill rhythm (Coleman et al., 1993; Norris et al.,1994b; D. Blitz, M. Coleman, B. Norris, and M. Nusbaum, unpublishedobservations). The MPN influence on these other projection neurons,and the gastric mill rhythms they elicit, remains to be determined.
Fig. 10. Schematic indicating the motor patterns elicited from the STG network as a result of activity in MCN1/CPN2 or MPN. Left, WhenMCN1 and CPN2 are active, specific versions of the pyloric rhythm(Bartos and Nusbaum, 1997) and gastric mill rhythm (Coleman andNusbaum, 1994; Norris et al., 1994a) are elicited. Right, WhenMPN is active, it excites the pyloric rhythm in the STG (Nusbaumand Marder, 1989a,b; present study) and inhibits MCN1 and CPN2,removing their excitation to the gastric mill system and eliminatingthe gastric mill rhythm (present study). This results in a distinctpyloric rhythm in the absence of the gastric mill rhythm. Darkcell bodies represent active neurons; light cell bodies representinactive neurons.
[View Larger Version of this Image (25K GIF file)]

Although proctolin superfusion to the STG mimics the effects of MPN on the pyloric rhythm, proctolin application does notmimic the effects of MPN stimulation on gastric mill rhythms.In fact, whereas MPN stimulation inhibits the gastric mill rhythm,application of proctolin to the CoGs excites MCN1 and CPN2 andthereby elicits the gastric mill rhythm (Blitz and Nusbaum, 1995).In addition to being proctolin-immunoreactive, MPN also exhibitsGABA-like immunoreactivity (Nusbaum et al., 1989). Although MPNelicits a proctolin-like pyloric motor pattern in the STG, itappears to use either GABA or a third, unidentified transmitterin the CoGs to inhibit the gastric mill rhythm.

The MPN-elicited increase in pyloric-timed activity of at least some gastric mill neurons is likely to be functionally effective.For example, in the intact crab Cancer pagurus, Heinzel et al.(1993) showed that the pyloric-timed activity of the MG neuronelicited pyloric-timed pumping movements of the lateral teeth.Although MPN often elicited action potentials in MG, this MG activitywas usually less intense than that occurring during gastric millrhythms. However, in C. pagurus, even two to three action potentialsper burst in MG elicits pumping movements of the lateral teeth(Heinzel et al., 1993). It is also possible that the depolarizedcomponent of the pyloric-timed oscillations in gastric mill neuronsthat occurs in response to MPN stimulation is sufficient to elicitpostsynaptic effects. STG neurons use action potentials to transmitsignals to their distant targets, but within the STG, they communicateprimarily via graded release of neurotransmitter (Raper, 1979;Graubard et al., 1983).

In addition to the MPN effects in the STG, some of the MPN effects on STG neurons are likely to result from its inhibitionof MCN1 and CPN2. For example, MCN1 excites DG (Nusbaum et al.,1992; Coleman and Nusbaum, 1994) and CPN2 inhibits DG (Norriset al., 1994a), whereas MPN has no direct effect on DG. Thus,the DG response to MPN stimulation during times when a gastricmill rhythm is not in progress depends partly on the level ofspontaneous activity in MCN1 and CPN2.

In the STNS of several different species, it has been shown that distinct motor patterns can be elicited from the STG networkby stimulation of different projection neurons (Nagy and Dickinson,1983; Dickinson et al., 1988; Katz and Harris-Warrick, 1990; Colemanet al., 1993; Coleman and Nusbaum, 1994; Norris et al., 1994a,b,1996). Unlike the MPN-elicited motor pattern, these selected motorpatterns appear to result entirely from the effects of each projectionneuron within the STG. Additionally, in the lobster Homarus gammarus,activation of the pyloric suppressor (PS) neuron eliminates thepyloric and gastric mill rhythms (Meyrand et al., 1994). PS neuronactivity assembles a different functional circuit that incorporateselements of several STNS networks, including some neurons fromthe gastric mill and pyloric circuits. Again, the incorporationof some STG neurons into this different circuit appears to resultfrom the actions of PS within the STG. However, recent work hasdemonstrated that after PS activity has ceased, there is a long-lastingactivation of the gastric mill rhythm that results in part fromPS activation of another projection neuron (Faumont et al., 1996).

In other systems, activation of neurons from other regions of the CNS also elicits distinct motor patterns from a common network.For example, stimulation of a single neuron in the crab braincan cause a switch from the forward to the reverse form of theventilation motor pattern (DiCaprio, 1990). Similarly, stimulationof different neurons in the cerebral ganglion of Aplysia can elicitdifferent feeding-related motor patterns (Rosen et al., 1991).These motor patterns appear to result from activation of overlappingsubsets of neurons. However, the extent to which distinct projectionneurons interact, separate from their direct influences on a commonnetwork, has not been elucidated in most systems. One system inwhich there is some information is the leech swimming system.Leech-swimming can be elicited by activation of a swim triggerneuron that directly influences swim gating and network neuronsand also inhibits a projection neuron, the activity of which inhibitsthe swim motor pattern (Brodfuehrer and Burns, 1995).

In this paper, we have shown that an identified modulatory projection neuron selects a specific motor output from a multifunctionalnetwork by direct modulation of pyloric circuit neurons to excitethe pyloric motor pattern and via inhibition of projection neurons,the activity of which would evoke the functionally related butdistinct gastric mill motor pattern (Fig. 10). We do not yet know,at the behavioral level, why MPN inhibits the gastric mill rhythm.One possibility, however, is that MPN does not suppress all formsof the gastric mill rhythm. Perhaps in the intact crab, MPN isnormally coactivated with one or more other projection neuronsthat elicit a distinct version of the gastric mill rhythm.

In addition to ensuring selection of particular motor patterns from a multifunctional network, interactions among parallelpathways might also be used effectively to increase the varietyof motor patterns produced by the targeted network. Such interactionsmight allow different combinations of projection neurons to becoactivated, thereby evoking distinct outputs from the affectednetwork. The behaviorally relevant pathways by which some projectionneurons are activated in the stomatogastric system have been identified(Nagy and Moulins, 1987; Simmers and Moulins, 1988; Blitz andNusbaum, 1996). For most, however, these pathways remain to bedetermined.

FOOTNOTES

Received March 14, 1997; revised April 14, 1997; accepted April 16, 1997.

This work was supported by National Science Foundation Grant IBN94-96264, National Institute of Neurological Disorders andStroke Grant NS-29436, National Institute of Mental Health TrainingGrant MH-17168, and the Human Frontiers Science Program.

Correspondence should be addressed to Dr. Michael P. Nusbaum, Department of Neuroscience, 215 Stemmler Hall, University ofPennsylvania School of Medicine, Philadelphia, PA 19104-6074.

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