Multiple Peptides Converge to Activate the Same Voltage-Dependent Current in a Central Pattern-Generating Circuit

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The Journal of Neuroscience, September 15, 2000, 20(18):6752-6759

Multiple Peptides Converge to Activate the Same Voltage-Dependent Current in a Central Pattern-Generating Circuit
Andrew M. Swensen and Eve Marder
Volen Center and Biology Department, Brandeis University, Waltham, Massachusetts 02454

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The stomatogastric ganglion of the crab, Cancer borealis, is modulated by >20 different substances, including numerous neuropeptides.One of these peptides, proctolin, activates an inward currentthat shows strong outward rectification (Golowasch and Marder,1992). Decreasing the extracellular Ca²⁺ concentration linearizes the current-voltage curve of the proctolin-inducedcurrent. We used voltage clamp to study the currents evoked byproctolin and five additional modulators [C. borealis tachykinin-relatedpeptide Ia (CabTRP Ia), crustacean cardioactive peptide, red pigment-concentratinghormone, TNRNFLRFamide, and the muscarinic agonist pilocarpine]in stomatogastric ganglion neurons, both in the intact ganglionand in dissociated cell culture. Subtraction currents yieldedproctolin-like current-voltage relationships for all six substances,and the current-voltage curves of all six substances showed linearizationin low external Ca²⁺. The lateral pyloric neuron responded to all six modulators,but the ventricular dilator neuron only responded to a subsetof them. Bath application of saturating concentrations of proctolinoccluded the response to CabTRP and vice versa. N-(6-Aminohexyl)-5-chloro-1-napthalensulfonamide,a calmodulin inhibitor, increased the amplitude and altered thevoltage dependence of the responses elicited by CabTRP and proctolin.Together, these data indicate that all six substances convergeonto the same voltage-dependent current, although they activatedifferent receptors. Therefore, differential network responsesevoked by these substances may primarily depend on the receptordistribution on networkneurons.

Key words: stomatogastric ganglion; crab; Cancer borealis; proctolin; CCAP; RPCH; crab tachykinin-related peptide; FLRFamide-related peptides

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Nervous systems contain many neuropeptides and amines that modulate synaptic strength and cellular excitability (Nicoll etal., 1990; Kupfermann, 1991; Marder and Calabrese, 1996; Marder,1998). Most voltage-dependent ion channels are subject to modulationby one or more substances, and many agonists modulate multiplemembrane currents (Kaczmarek and Levitan, 1987; Levitan, 1988,1994; Hille, 1992, 1994; Gudermann et al., 1997). In principle,the large number of different intrinsic and synaptic currentssubject to modulation could provide the potential substrate forvirtually infinite modifications of circuit behavior under differentmodulatory conditions. Nonetheless, there are numerous examplesof convergent actions of modulators, in which several substancesact on the same current (Dunlap and Fischbach, 1978; Jones, 1985;Christie and North, 1988; Nicoll et al., 1990; Bolshakov et al.,1993; Brezina et al., 1994a,b; van Tol-Steye et al., 1997; Sodicksonand Bean, 1998). Convergent actions of modulators may appear tobe redundant at the level of the single neuron but may not beredundant at the level of network behavior, if different substancesactivate different receptors on separate populations of targetneurons.

The crustacean stomatogastric ganglion (STG) contains the neurons responsible for producing the well described pyloric andgastric mill rhythms (Selverston et al., 1976; Harris-Warricket al., 1992). The pyloric and gastric mill rhythms are modulatedby a large number of peptides and amines that are present as circulatinghormones and/or are released from modulatory projection and sensoryneurons (Marder, 1987; Harris-Warrick et al., 1992; Christie etal., 1995; Marder et al., 1995; Marder and Calabrese, 1996). Despitethe extensive study of the effects of modulators on the STG motorpatterns (Marder and Calabrese, 1996; Marder et al., 2000) onlyproctolin and the amines have been studied with voltage-clampmethods. Proctolin activates an inward nonspecific cation current(Golowasch and Marder, 1992) that shows strong outward rectificationwith a peak current at approximately $-$ 50 mV and a reversal potentialof ~0 mV. Additionally, in low external calcium the current-voltagecurve for the proctolin-induced current linearizes. Serotoninand dopamine modulate several of the voltage-gated currents inSTG neurons (Kiehn and Harris-Warrick, 1992a,b; Harris-Warricket al., 1995a,b; Zhang and Harris-Warrick, 1995; Kloppenburg etal., 1999).

In this paper we study the effects of six neuromodulators [proctolin, Cancer borealis tachykinin-related peptide Ia (CabTRP),crustacean cardioactive peptide (CCAP), red pigment-concentratinghormone (RPCH), TNRNFLRFamide, and the muscarinic agonist pilocarpine].These modulators all have excitatory effects at the network leveland are able to activate the pyloric rhythm in quiescent preparations(Hooper and Marder, 1984; Marder and Hooper, 1985; Nusbaum andMarder, 1988; Weimann et al., 1993, 1997; Christie et al., 1997b).We show here that these substances appear to activate the samecurrent. However, different target neurons in the stomatogastricganglion respond to different subsets of these substances. Thus,it is possible that modulators that activate the same membranecurrent can still elicit different actions at the networklevel.

Parts of this paper have been published previously in abstract form (Swensen and Marder, 1998).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals. Experiments were performed on C. borealis purchased from Commercial Lobster (Boston, MA). Animals were maintainedin artificial seawater at 12-15°C untilused.

Ganglion recordings. Stomatogastric nervous systems were dissected out of the animals. Extracellular pin electrodes were usedto record from nerves, and an Axoclamp 2A amplifier (Axon Instruments,Foster City, CA) was used for intracellular recordings. All preparationswere continuously superfused (3-7 ml/min) with chilled (11-13°C)physiological saline. Microelectrodes for intracellular recordingswere filled with 0.6 M K₂SO₄ and 20 mM KCl and had resistancesof 20-40 M $Omega$ . Data were collected and analyzed using pCLAMP software(Axon Instruments). Recordings of ganglion neurons in situ weredone in two-electrode voltage-clamp (TEVC) or two-electrode current-clampmodes.

STGs were isolated from higher ganglia using a sucrose block of the stomatogastric nerve and/or bath-applied 0.1 µM tetrodotoxin(TTX; Alomone Laboratories, Jerusalem, Israel). Neurons were pharmacologicallyisolated using 10 µM picrotoxin (PTX; Sigma, St. Louis, MO). Theeffects of various modulators on the lateral pyloric (LP) andventricular dilator (VD) neurons were examined. Each STG containsa single LP neuron and a single VD neuron. TTX was used to blockaction potential generation, and 10 mM tetraethylammonium chloride(Sigma) was sometimes used in recordings to block some of theK⁺currents.

Culture recordings. Cultured neurons were recorded using single-electrode current and voltage clamp using an SEC-05L amplifierfrom Npi Electronic GmbH (Tamm, Germany). Microelectrodes anddata collection and analysis were the same as for ganglion recordings.Cultured cells were unidentified neurons from the STG and werestudied 2-4 d afterplating.

Culture techniques. STG neurons were plated into dissociated cell culture using minor modifications of previously describedmethods (Turrigiano and Marder, 1993; Turrigiano et al., 1994,1995). STGs were removed from the animal, desheathed, and treatedat room temperature for 1 hr with 2% dispase II (Boehringer Mannheim,Mannheim, Germany) in Ca²⁺- and Mg²⁺-free saline. They were then washed at 12°C in physiological salinefor at least 2 hr and sometimes overnight. Cells were then pulledoff the STG by suction using fire-polished electrodes and platedout onto Nunclon culture dishes (Nunc, Naperville, IL) containingculture medium. The medium was composed of sterile Leibowitz-15(Life Technologies, Gaithersburg, MD) diluted 1:1 with C. borealisstock solution and 25 µg/ml gentamycin (Life Technologies). Cultureswere incubated 2-4 d at 12°C beforerecording.

Solutions. C. borealis physiological saline was composed of (in mM): NaCl, 440; KCl, 11; CaCl₂, 13; MgCl₂, 26; Trizma base,11; and maleic acid, 5, pH 7.4-7.5. C. borealis stock solutioncontained (in mM): NaCl, 740; KCl, 16; CaCl₂, 25; MgCl₂, 50; andHEPES, 14, pH 7.7.

Modulators. Proctolin (Sigma), CabTRP Ia (a gift from A. E. Christie and M. P. Nusbaum, Department of Neuroscience, Universityof Pennsylvania School of Medicine, Philadelphia, PA), CCAP (Bachem,Torrance, CA), RPCH, TNRNFLRFamide (American Peptide Company),and Pilocarpine (Sigma) were dissolved in saline and either pressure-appliedusing a Picospritzer (5-15 psi, 50-600 msec) or bath-applied bymeans of a switching port in the continuously flowing superfusionsystem.

Other chemicals. N-(6-Aminohexyl)-5-chloro-1-napthalensulfonamide (W-7; Sigma) was used at 3.3 × 10⁴ M. The Ca²⁺ chelator 1,2-bis(2aminophenoxy)ethane-N,N,N',N'-tetraacetic acid(BAPTA) tetrapotassium salt (Sigma) was injected into cells usingelectrodes containing 200 mM BAPTA. The protein kinase C- andcyclic nucleotide-dependent protein kinase inhibitor 1-(5-isoquinolinesulfonyl)-2-methyl-piperazine)dihydrochloride (H-7; Sigma) was bath-applied at 100 µM. The phospholipaseC and A₂ inhibitor 1-(6-((17 $beta$ )-3-methoxyestra-1,3,5(10)-trien-17-yl)amino)hexl)-1H-pyrrole-2,5-dione(U-73122; Sigma) was bath-applied at 300 µM.

Current-voltage curves. To obtain I-V curves, voltage-clamped cells were typically ramped from $-$ 90 to 0 mV in 1.2 sec (75mV/sec). Currents elicited in control conditions were subtractedfrom currents elicited with the peptide applied to obtain differenceI-V curves. Multiple ramps were done during the responses to singlepuffs or bath application, and the maximal subtracted currentduring each application was used to characterize the V_peak andamplitude of theresponse.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Each STG has a single LP neuron. A large number of neuromodulators, including proctolin, RPCH, CCAP, TNRNFLRFamide, and CabTRP,cause the LP neuron to increase its excitability during ongoingpyloric rhythms (Marder et al., 1986; Nusbaum and Marder, 1988;Weimann et al., 1993, 1997; Christie et al., 1997b). We were interestedin determining the currents that are responsible for this increasedexcitability in these substances. As a first step, we wished todetermine whether each of these substances acted directly on theLP neuron. Therefore, preparations were placed in 10⁵ M PTX, which blocks much of the chemical inhibitory transmissionin the STG (Marder and Eisen, 1984), and the modulators appliedeither in the bath or from pufferpipettes.

Figure 1 shows current-clamp recordings of the same LP neuron in response to short bath applications of each of the six modulatorsstudied here. These recordings illustrate that all of the modulatorsdepolarized the LP neuron and caused it to fire strongly and insome cases to burst. Applications under these recording configurationswere done in six preparations for RPCH, CabTRP, and TNRNFLRFamideand in five preparations for proctolin, CCAP, and pilocarpine.All six modulators were applied to the same preparation a totalof three times.

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Figure 1. Effects of pilocarpine, CabTRP, TNRNFLRFamide, RPCH, CCAP, and proctolin on a semi-isolated LP neuron. The STG was superfused with C. borealis physiological saline containing 10 µM picrotoxin to block inhibitory glutamatergic synapses, and the STG was isolated from higher ganglia using a sucrose block of the stomatogastric nerve. Modulators were bath-applied for 45 sec at a concentration of 3 × 10⁵ M (pilocarpine), 4 × 10⁷ M (CabTRP, TNRNFLRFamide), 3 × 10⁷ M (RPCH), or 2 × 10⁷ M (CCAP, proctolin). Recordings are all from the same preparation, which was washed for 12-15 min between applications. The baseline membrane potential for each trace is $-$ 55 mV. The vertical arrow indicates the starting time of the modulator bath applications.

Because there is extensive electrical coupling and there are connections between STG neurons and descending modulatory inputs(Coleman et al., 1995), it is impossible to isolate STG neuronscompletely from all circuit interactions while in the network.Therefore, we studied the currents evoked by these modulatorsin individual neurons in dissociated cell culture, as well asin the intact ganglion. The cultured neurons have an additionaladvantage, because their much reduced electrotonic structure makesit possible to obtain better voltage-clampcontrol.

Turrigiano and Marder (1993) showed that identified STG neurons retain their characteristic responses to modulators when platedinto dissociated cell culture. Specifically, in culture, eachidentified cell type responded to the same substances to whichit responds in the intact ganglion and failed to respond to substancesto which it does not respond in the intact ganglion. Because STGneurons must be physiologically identified using intracellularrecordings before dissociation, it is extremely difficult to obtaina large number of identified cultured neurons. By combining dataon cultured neurons and neurons in the intact ganglion (see below),we were able to verify that the properties of the current we measuredin ganglion neurons were not complicated by circuitinteractions.

Proctolin activates a voltage-dependent inward current

In STG neurons, proctolin evokes a small inward current that shows strong outward rectification (Golowasch and Marder, 1992).Figure 2 shows voltage-clamp recordings from an LP neuron in theganglion that illustrate the characteristic voltage dependenceof the proctolin-induced current. In this experiment, the neuronwas held at the voltages indicated, and proctolin was pressure-appliedat the time indicated by the arrow. The inward current elicitedat $-$ 40 mV was larger than the currents elicited at $-$ 20 and $-$ 60mV. The voltage dependence of the proctolin-induced current, andspecifically the voltage at the peak inward current (V_peak), canbe seen more clearly using difference currents derived from voltageramps. Figure 3A shows the total cell currents elicited from acultured neuron in response to voltage ramps from $-$ 90 to 0 mVin the absence and presence of proctolin. The control I-V curveis plotted with a black line, and the I-V curve in the presenceof proctolin is plotted with a dotted line. Figure 3B shows thecurrent that results from the subtraction of these two curves.Note that there is a net inward current with a peak at approximately $-$ 18 mV and strong outward rectification. Thirteen of 51 (25%)cultured neurons responded to proctolin with this same characteristicinward current. The remaining cultured neurons showed no responseto proctolin. The V_peak was measured in 7 of these 13 neuronsand varied from $-$ 15 to -30 mV (mean, $-$ 25 ± 5.3 mV).

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Figure 2. Proctolin elicits an inward current with an unusual voltage dependence. The peak proctolin response in this LP neuron was elicited at approximately $-$ 40 mV and decreased in amplitude for more positive ( $-$ 20 mV) and more negative ( $-$ 60 mV) membrane potentials. Proctolin was pressure-applied at 4 × 10⁴ M (400 msec) to the STG neuropil. This recording was made using TEVC in the presence of 10 µM PTX and 0.1 µM TTX.

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Figure 3. Proctolin and CabTRP currents in an unidentified cultured stomatogastric neuron. A, Total cell currents elicited in response to voltage ramps from $-$ 90 to 0 mV (75 mV/sec) in the absence (solid line) and presence (dotted line) of bath-applied proctolin. B, Proctolin I-V curve obtained by subtracting the total cell currents elicited by the voltage ramps in A. C, CabTRP difference I-V curve from the same neuron as in A.

Multiple modulators activate a similar inward current

In addition to responding to proctolin, the neuron shown in Figure 3, A and B, also responded to CabTRP (Fig. 3C). CabTRPalso evoked an inward current with a peak amplitude at $-$ 18mV.

When cultured neurons responded to both proctolin and CabTRP, the differences in the V_peak values of the two responses were<5 mV (n = 3). Forty-four of 88 cultured neurons tested (50%)responded to CabTRP. All neurons that responded to CabTRP didso with the same characteristic inward current. Overall, V_peakfor CabTRP varied from $-$ 20 to $-$ 46 mV (mean, $-$ 37 ± 6 mV; n = 24).The difference between the mean V_peak values of the proctolinand CabTRP currents appear to be attributable to the fact thatthere were V_peak variations between individual neurons, and onlythree neurons in the proctolin- and CabTRP-responding populationsoverlapped.

Golowasch and Marder (1992) showed that the current-voltage curve of the proctolin-induced current linearized in low externalCa²⁺. We verified that this was the case in the responses of culturedneurons to proctolin (data not shown). Figure 4, top left, showsthe current-voltage curve for CabTRP from a cultured neuron incontrol saline (13 mM Ca²⁺) and in low Ca²⁺ saline (0.1 mM Ca²⁺). In low Ca²⁺, the current-voltage curve linearized, and there was a largeincrease in the current amplitude (n = 6). Figure 4 also showsexamples of the current-voltage curves for TNRNFLRFamide, CCAP,and pilocarpine in control and low-Ca²⁺ saline. The current-voltage curves for TNRNFLRFamide (n = 3),CCAP (n = 2), RPCH (n = 3), and pilocarpine (n = 2) all linearizedin low Ca²⁺ saline. These results demonstrate that all of these substancesactivate a current with the same general features, suggestingthat they activate the same current.

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Figure 4. Linearization of I-V curves for CabTRP, TNRNFLRFamide, pilocarpine, and CCAP in low external Ca²⁺. Control I-V curves were obtained in normal external Ca²⁺ (13 mM). Low-calcium saline contained 0.1 mM Ca²⁺. Curves for CabTRP, TNRNFLRFamide and pilocarpine were obtained from SEVC recordings of cultured neurons. The CCAP curve was obtained from a TEVC recording of the LP neuron (semi-intact preparation) in the presence of 10 µM PTX and 0.1 µM TTX. In each individual graph, control and low-Ca²⁺ responses are from the same neuron. Each graph, however, shows results from a separate neuron. CabTRP (10⁶ M), TNRNFLRFamide (10⁶ M), and pilocarpine (3 × 10⁵ M) were bath-applied. CCAP (10⁴ M) was pressure-applied to the ganglion neuropil.

Figure 5 shows current-clamp recordings from a single cultured neuron that responded to CabTRP, proctolin, TNRNFLRFamide,and CCAP. Each of these substances evoked similar changes in theactivity of the cell, showing that completely isolated neuronsdo respond similarly in response to the multiple modulators thatactivate the same current. Most of the individual cultured neurons,however, were only tested for responses to a small subset of thesix modulators, making it impossible to draw any quantitativeconclusions about the frequency of coexpression of the variousmodulator receptors.

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Figure 5. CabTRP, proctolin, TNRNFLRFamide, and CCAP all elicited similar effects in this cultured neuron. Modulators were bath-applied at 10⁶ M, and responses were recorded in current clamp. The neuron was depolarized using a constant current injection to trigger membrane oscillations. The horizontal line indicates $-$ 20 mV.

The LP neuron responds to all six of these substances with the same current

All six of the modulators tested elicit the same current in the LP neuron in the intact STG. Figure 6A shows the current-voltagecurves for proctolin, CabTRP, CCAP, and RPCH taken from the sameLP neuron. Note that each evoked an inward current with a V_peakbetween $-$ 50 and $-$ 40 mV. TNRNFLRFamide and pilocarpine (data notshown) had similar I-V curves for this LP neuron. The currentsevoked by each of these substances showed the same characteristiclinearization in low external Ca²⁺ (data not shown). Table 1 shows the properties of the currentsevoked by each of the substances in LP neurons. The V_peak of thecurrents evoked by each of these substances were statisticallyindistinguishable (one-way ANOVA, p = 0.078). The LP neuron alwaysresponded to each of these substances whenever they were applied.

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Figure 6. Convergence of modulators onto the LP and VD neurons. A, I-V curves for proctolin, CabTRP, CCAP, and RPCH from an LP neuron. All yielded similar I-V curves with their peak currents occurring at very similar voltages (approximately $-$ 45 mV). Recordings are from the same LP neuron. B, I-V curves for proctolin and CabTRP from a VD neuron with peak currents occurring at similar voltages (approximately $-$ 20 mV). Unlike the LP neuron, the VD neuron shows no response to RPCH or CCAP. Recordings are from the same VD neuron. Modulators were pressure-applied at 10⁴ M to the ganglion neuropil. The LP and VD neurons also responded to TNRNFLRFamide and pilocarpine (data not shown) with currents similar to those shown. Recordings were made using TEVC in the presence of 10 µM PTX, 0.1 µM TTX, and 10 mM tetraethylammonium chloride.


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Table 1. Characteristics of the modulator currents in the LP neuron

The VD neuron responds to a subset of the substances

Unlike the LP neuron, the VD neuron does not respond to CCAP (n = 4) or RPCH (n = 5). The VD neuron does respond to the remainingfour substances (proctolin, CabTRP, TNRNFLRFamide, and pilocarpine),which all elicit currents with the same characteristic I-V curve.Figure 6B shows examples of the I-V curves for proctolin and CabTRPin a VDneuron.

The subtraction currents for CCAP and RPCH, which do not activate a current in the VD neuron, are also shown. The V_peak ofthe current seen in response to the modulators in the VD neuronwas close to $-$ 20 mV (Table 2), considerably more depolarizedthan that seen in the LP neuron. The V_peak values of the currentsin these VD neurons evoked by the different modulators were statisticallyindistinguishable (one-way ANOVA, p = 0.430). However, V_peak valuesmeasured in the VD and LP neurons were statistically different(p < 0.001, Student's t test). The VD neuron always respondedto this same subset of peptides.


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Table 2. Characteristics of the modulator currents in the VD neuron

Coapplication of CabTRP and proctolin to LP results in occlusion

If multiple modulators converge on the same set of ion channels, one would expect that saturating concentrations of one modulatorwould occlude responses to a second modulator. We tested thisusing proctolin and CabTRP. We found that saturating concentrationsof proctolin and CabTRP resulted in occlusion of the responseto the other peptide. We first performed experiments to obtaindose-response curves for the two peptides. In these experiments,the LP neuron was voltage-clamped to $-$ 40 mV, the peptides werebath-applied, and the currents were recorded. Figure 7A showsan example of the currents resulting from 3 × 10⁸, 3 × 10⁷, and 3 × 10⁶ M proctolin, respectively, from one experiment. Figure 7B showsthe plotted mean dose-response curves for proctolin and CabTRP(n = 5 for proctolin and n = 3 for CabTRP). As calculated fromthe fits, 90% saturation was reached at 1.8 × 10⁶ M proctolin and 2.0 × 10⁶ M CabTRP.

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Figure 7. Dose-response curves for proctolin and CabTRP in the LP neuron. A, Representative voltage-clamp traces from bath application of varying concentrations of proctolin. B, Dose-response curves for proctolin (n = 5) and CabTRP (n = 3). For each individual experiment, peak currents were normalized to the largest response. Responses across all experiments were then averaged and plotted ± SE. Recordings were made using TEVC in the presence of 10 µM PTX and 0.1 µM TTX. The fits to the data points were done to the curve y = I_maxx/(K_d + x), where x is the concentration of the applied peptide, I_max is the normalized maximal current, and K_d is the dissociation constant. For proctolin, I_max = 1.06 ± 0.01, and K_d = 2.02 ± 0.01 × 10⁷ M. For CabTRP, I_max = 0.97 ± 0.03, and K_d = 2.25 ± 0.29 × 10⁷ M.

Figure 8A shows the current evoked by a proctolin puff in control conditions and in the presence of 2 × 10⁶ M bath-applied CabTRP. Note that the steady inward current evokedby the bath application of the CabTRP was slightly larger thanthat of the proctolin puff in control conditions, and the responseevoked by the proctolin puff during the CabTRP response was virtuallyoccluded (n = 3). Figure 8B shows the reverse experiment, in whichCabTRP was applied first in control saline and then during a bathapplication of 2 × 10⁶ M proctolin. Again, the response to the puff was occluded whenit was applied with a near-saturating concentration of the otherpeptide in the bath (n = 3).

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Figure 8. Occlusion of the peptidergic responses in the LP neuron. A, The response to proctolin is occluded by bath application of CabTRP. B, The response to CabTRP is occluded by bath application of proctolin. The LP neuron was voltage-clamped at $-$ 50 mV. The dotted line represents the baseline current. The offsets in the right traces are caused by the steady-state current produced by the bath-applied peptides. Proctolin (A) and CabTRP (B) were pressure-applied (10⁴ M) to the ganglion neuropil. Recordings were made using TEVC in the presence of 10 µM PTX and 0.1 µM TTX.

W-7 augments the proctolin and CabTRP currents and alters their voltage dependence

It would be of obvious interest to determine the identity of the second messenger systems involved in the activation of thischannel by the modulators. Therefore, we tried a number of pharmacologicalagents known to influence second messenger signaling pathwaysin other species. BAPTA (n = 4) gave ambiguous results. H-7 (n= 2) and U-73122 (n = 2) had no apparent effect. However, thecalmodulin inhibitor W-7 (Hidaka et al., 1980; Itoh and Hidaka,1984) had a robust effect on the current. Bath application of3.3 × 10⁴ M W-7 increased the amplitude of the currents evoked by bothproctolin and CabTRP in the LP neuron. The most interesting aspectof this effect is that W-7 also altered the voltage dependenceof the currents (Fig. 9). In this experiment, proctolin puffswere applied in control saline at both $-$ 40 and $-$ 80 mV. Note thatthe control response at $-$ 80 mV was smaller than that at $-$ 40 mV(consistent with the characteristic I-V curve of this current).However, in W-7 the amplitude of the response at $-$ 80 mV was muchlarger than that at $-$ 40 mV (n = 3 preparations). Similar datawere obtained with CabTRP (n = 3 preparations).

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Figure 9. The calmodulin inhibitor W-7 (bath-applied, 3.3 × 10⁴ M) increases the amplitude of the peptidergic current and alters its voltage dependence. In control conditions, proctolin elicits a larger current at $-$ 40 than at $-$ 80 mV. In the presence of W-7, the amplitude of the elicited current at both membrane potentials increases, and the elicited response becomes larger at $-$ 80 than at $-$ 40 mV. Proctolin was pressure-applied at 4 × 10⁴ M to the ganglion neuropil. Recordings are from an LP neuron using TEVC in the presence of 10 µM PTX and 0.1 µM TTX.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Nervous systems contain a vast number of signaling molecules, including amino acids, amines, and neuropeptides. Although extensiveneuroanatomical and immunocytochemical work has demonstrated complexand rich patterns of colocalization for amines and peptides, howthese substances modulate specific functional circuits remainsrelatively unknown. The stomatogastric nervous system contains~20 different identified modulatory substances (Marder and Weimann,1992; Marder et al., 1995; Christie et al., 1997a; Abbott andMarder, 1998), each of which can alter the STG motor patterns.The effects of serotonin (Kiehn and Harris-Warrick, 1992a,b; Zhangand Harris-Warrick, 1995), dopamine (Harris-Warrick et al., 1995a,b;Kloppenburg et al., 1999), and the peptide proctolin (Golowaschand Marder, 1992) have been characterized, but until now, thebiophysical actions of most of the modulatory substances foundin inputs to the STG wereunknown.

Voltage dependence of the modulator current

We predominantly used ramps in this study because they provided a simple method for obtaining a quantitative value for V_peak,which otherwise would have required interpolation among pointstaken at different holding potentials, and they allowed us toobtain the full I-V curve during a single application of modulator.Deriving I-V curves using voltage ramps can sometimes give inaccurateresults depending on the voltage and time dependence of the currentbeing characterized. Nonetheless, Figures 2 and 9 show that thevoltage dependence captured in the ramps is also seen in the currentsevoked at fixed holding potentials, as was described in previouswork on the proctolin-induced current (Golowasch and Marder, 1992).

The experiments reported here demonstrate that six different substances converge on a voltage-dependent inward current whosecurrent-voltage curve linearizes in low-Ca²⁺ solutions. V_peak differed for different identified cell types,although for an individual neuron, all of the peptides that actedon that neuron evoked a current with a similar voltage dependence.V_peak ranged from $-$ 55 to $-$ 15 mV in different cultured neurons,and the identified VD and LP neurons had statistically differentV_peak values. V_peak for the LP neuron reported in this study ismore depolarized than the value for the peak response previouslyreported (Golowasch and Marder, 1992). In the previous study,the mean peak voltage was calculated using the amplitudes of responsesmeasured in both current clamp and voltage clamp and with a varietyof protocols, whereas all of the data reported here were obtainedas difference currents calculated from ramps, and we assume thatthis discrepancy results from differences in experimentalmethods.

The differences in the voltage dependence of different cell types could arise from a number of different scenarios: (1) differentcell types could express channels with different subunit compositions;(2) different cell types could have more or less extensive phosphorylationof the channel; and (3) some cell types could have an additionalpeptide-modulated voltage-dependent current that contributes tothe net current as we have measured it. At present we have noway to distinguish among these possibilities, but note that withinan individual neuron, all active peptides evoke currents witha similar voltage dependence, arguing that whatever mechanismis responsible for the cell-type differences, it is independentof the identity of the activatingpeptide.

Sharp (1994) used the dynamic clamp to apply the proctolin current to both the LP and anterior burster neurons of the STGand found that the V_peak of the artificial proctolin current hadto be carefully matched to the intrinsic properties of each neuronto reproduce the actions of exogenously applied proctolin. Therefore,each neuron may tune this modulator current so that its voltagedependence is set with regard to the other voltage-dependent currentsfound in the neuron. For example, it is possible that the voltagedependence of the proctolin-induced current in the LP neuron istuned to enhance the ability of the LP neuron to generate burstsand plateau properties, but the more depolarized current in theVD neuron is tuned to influence spike rate but not to enhancebursting.

Where does convergence occur?

Other examples of modulator convergence are abundant in both invertebrates (Brezina, 1988; Bolshakov et al., 1993; van Tol-Steyeet al., 1997, 1999) and vertebrates (Andrade and Aghajanian, 1985;Jones, 1985; Andrade et al., 1986; Christie and North, 1988; Bleyand Tsien, 1990; Nicoll et al., 1990; Cox and Dunlap, 1992; Sodicksonand Bean, 1998). It is simplest to assume that the convergenceof the different modulators onto the same current in this studyoccurs subsequent to receptor binding. The agonists studied herehave very different structures, and it would be quite unexpectedif they bind to the same receptor. Moreover, if they were somehowable to bind to a very promiscuous receptor, then one would predictthat any neuron that responded to one of the substances wouldrespond to all of them. Our work in culture and in the ganglionshows that this is not thecase.

The finding that the peptide responses occlude each other suggests that they act on the same channels and that the convergenceis occurring either at some intermediate level of the signal transductionpathway or at the level of the channel itself. This interpretationis also supported by the fact that W-7 alters the amplitude andvoltage dependence of both the proctolin and CabTRP currents.Work in other systems suggests that convergence often occurs earlyin the signal transduction pathway upstream from the actual ionchannel (Andrade and Aghajanian, 1985; Andrade et al., 1986; Bolshakovet al., 1993; Brezina et al., 1994b; Jones et al., 1995; van Tol-Steyeet al., 1999), although substances with convergent effects canact through different second messenger pathways (Elmslie, 1992;Diversé-Pierluissi and Dunlap, 1993, 1995).

Despite extensive work on the modulation of STG networks, much less is known concerning the second messenger pathways underlyingthat modulation. Proctolin does not appear to increase cAMP levelsin STG neurons (Flamm et al., 1987; Hempel et al., 1996). TheW-7 data (Fig. 9) suggest that a calmodulin-sensitive step ispossibly implicated in the activation of this channel or in itsmodulation, but much further work will be needed to determinethe signal transduction pathways activated by thesesubstances.

Functional consequences of convergence for circuit modulation

Dopamine and serotonin both modulate several voltage-dependent conductances in STG neurons (Kiehn and Harris-Warrick, 1992a,b;Harris-Warrick et al., 1995a,b; Zhang and Harris-Warrick, 1995;Kloppenburg et al., 1999). Therefore, it was natural to assumethat many of the other modulators would also alter multiple voltage-dependentcurrents in STG neurons. The result reported here is interestingfor two reasons. First, it is surprising that so many substancesconverge on the same current. Examples of this large degree ofconvergence are relatively rare (Sodickson and Bean, 1998). Second,it is surprising that so many of the actions of these peptideson the motor patterns generated by the STG can be attributed tomodulation of a single current, as demonstrated with dynamic clampapplications of a model proctolin current, which mimic well theactions of proctolin (Sharp et al., 1993a,b; Abbott and Marder,1998). Nonetheless, these peptides may evoke additional, as yetuncharacterized actions that are responsible for their effectson synaptic transmission (Dickinson et al., 1990; Marder et al.,1997) or could influence membraneexcitability.

Our description of the response characteristics for the VD and LP neurons suggests that different neuronal types respond tovarious subsets of the peptides. The output of the network asa whole will be strongly influenced by the distribution of peptidereceptors on different neurons. This would be a particularly usefulmechanism for the selection of different motor patterns in responseto nonlocalized release from neurohemal-like terminals withinthe STG (Kilman and Marder, 1996) or to substances that reachthe STG hormonally (Christie et al., 1995).

What are the consequences for circuit modulation of the modulator convergence reported here? At first glance, the convergenceof all of these modulators onto the same current appears to reducethe potential for circuit flexibility. However, the number anddistribution of receptors to each substance will allow each oneto produce characteristic and different actions at the networklevel. Additionally, these modulators could have divergent effectson other membrane currents and/or synaptic transmission, whichcould also help contribute to the differential network effectsof these modulators. Another mechanism to allow the nervous systemto maintain a wide range of outputs could be through the colocalizationof various modulators. Proctolin and CabTRP are colocalized inmodulatory commissural neuron 1 (MCN1), but MCN1 activation resultsin a different motor pattern than that evoked by other proctolin-containingneurons (Blitz et al., 1999) that contain differentcotransmitters.

The extensive convergence of these modulators could also contribute to network stability. The large numbers of modulatorsand sites of modulatory action in the STG make it difficult tounderstand how networks are protected against "overmodulation."Each of the modulators studied here could produce a unique actionat the level of the whole network, but because they occlude theactions of each other, the response of a given neuron to multiplemodulators will be limited or held in check. Convergence may actuallycontribute to limiting the number of possible network configurationsand, therefore, may serve as a stabilizingforce.

  FOOTNOTES

Received Feb. 22, 2000; revised June 12, 2000; accepted June 26, 2000.

This research was supported by National Institutes of Health Grant NS17813 and the W. M. Keck Foundation. We thank Dr. JorgeGolowasch and Dr. Kathryn S. Richards for helpful discussionsandcomments.
Correspondence should be addressed to Dr. Eve Marder, Volen Center, MS 013, Brandeis University, 415 South Street, Waltham,MA 02454-9110. E-mail: marder{at}brandeis.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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