Immunocytological and Biochemical Localization and Biological Activity of the Newly Sequenced Cerebral Peptide 2 in Aplysia

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Volume 16, Number 24, Issue of December 15, 1996 pp. 7841-7852
Copyright ©1996 Society for Neuroscience

Immunocytological and Biochemical Localization and Biological Activity of the Newly Sequenced Cerebral Peptide 2 in Aplysia

Gregg A. Phares and Philip E. Lloyd
Committee on Neurobiology and Department of Pharmacological and Physiological Sciences, University of Chicago, Chicago, Illinois 60637

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Cerebral peptide 2 (CP2), a 41 amino acid neuropeptide, was identified because it was transported from the cerebral gangliaof Aplysia to other central ganglia. Immunocytology indicatesthat CP2 is distributed widely in the CNS and peripheral tissuesof Aplysia. Most CP2-immunoreactive neurons were found in thecerebral ganglia and extensively overlap with the distributionof cerebral peptide 1 (CP1). HPLC analyses confirm that individualcerebral neurons synthesize both CP1 and CP2. In other ganglia,CP1 and CP2 are localized predominantly to different neurons.CP2-immunoreactive fibers and varicosities are present in theneuropil of all ganglia but were found surrounding cell bodiesand axon hillocks most often in the buccal and abdominal ganglia.Thus, the effects of CP2 on neurons in these ganglia were determinedusing intracellular recording. In the buccal ganglia, CP2 evokesrhythmic activity in many motor neurons that seems similar tothat observed during ingestion; however, only one identified neuronwas found to be depolarized directly. By contrast, in the abdominalganglion, many neurons are depolarized directly by CP2. A numberof these have been shown to be part of the circuit that regulatesrespiratory pumping. Injection of CP2 into freely behaving Aplysiaincreases the rate of respiratory pumping and causes other changesin behavior. CP2 is stable in hemolymph, which raises the possibilitythat it may act as a hormone. Thus, CP2 is a bioactive neuropeptidethat is present in many neurons and likely functions as a transmitteror a hormone.
Key words: neuropeptide; immunoreactivity; cerebral ganglia; identified neurons; axonal transport; peptide biosynthesis

INTRODUCTION

We have been studying peptidergic synaptic transmission in Aplysia and have recently begun to characterize previously unidentifiedpeptides that may be important in interganglionic communication.The CNS of Aplysia is composed of five major ganglia linked togetherby connective nerves. Peptide transmitters that are used for communicationbetween ganglia would be expected to be synthesized in neuronalcell bodies in one ganglion and transported by fast axonal transportvia axons in the connective nerves to release sites in targetganglia. Neuropeptides transported from the cerebral ganglia toother ganglia may be particularly important in behavioral regulation,because the cerebral ganglia receive input from many sensory structuresand seem to be involved in the higher-order control of many behaviors(Kandel, 1979). Although neurons in the cerebral ganglia thatare involved in the initiation or modulation of behavior havebeen identified, little is known about the neuropeptides theymay use as transmitters.

In a series of experiments that studied fast axonal transport of [³⁵S]methionine-labeled peptides between central ganglia, severalpreviously uncharacterized peptides were found to be synthesizedin the cerebral ganglia and transported primarily to the abdominaland pedal ganglia (Lloyd, 1989). Two of these peptides, termedcerebral peptide 1 (CP1) and CP2, were targeted for purification(Phares and Lloyd, 1996; Phares et al., 1996). With the use ofsequential modes of HPLC, radiolabeled peptide probes generatedby transport experiments were used to monitor the purificationsfrom extracts of cerebral ganglia. Both peptides were purifiedand sequenced: CP1 is a 13 amino acid peptide with no post-translationalmodifications; CP2 is a 41 amino acid peptide with an amidatedC terminal (Phares and Lloyd, 1996; Phares et al., 1996).

The immunocytological distribution of CP1 in the CNS of Aplysia has been described (Phares and Lloyd, 1996). Neuronal cellbodies containing CP1-like immunoreactivity (CP1-lir) were foundin each of the major ganglia, but the majority was located inthe cerebral ganglia. In the present study, we report the distributionof CP2-lir in the CNS and certain peripheral structures. Neuronscontaining CP2-lir were found throughout the CNS but were mostnumerous in the cerebral ganglia, with a distribution similarto neurons positive for CP1-lir. Immunocytological and biochemicalresults presented here suggest that CP1 and CP2 are often butnot always colocalized in neurons. Fibers containing CP1-lir andCP2-lir were found throughout the CNS and in a number of peripheraltissues. We also found that a number of identified neurons inthe buccal and abdominal ganglia responded electrophysiologicallyto CP2, and that injection of CP2 into an animal reliably elicitsa number of behavioral responses. Thus, we have identified inCP2 a new neuropeptide that seems to be involved in synaptic transmissionbetween neurons in the cerebral ganglia and neurons in the remainderof the CNS.

MATERIALS AND METHODS
Animals Aplysia californica (1-250 gm) were obtained from Marinus (Long Beach, CA) and maintained in circulating artificial seawater(ASW) tanks at 15°C. Before dissection, the animals were immobilizedby an injection of isotonic MgCl₂ equal to 50% of their body weight.
Antisera The amino acid sequence of CP1, NH₂-FSGLMSEGSSLEA-COOH, and the anti-CP1 serum 1693 used in this study have been described(Phares and Lloyd, 1996). The amino acid sequence of CP2, nh₂-FDFGFAGLDTYDAIHRALEQPARGTSNSGSGYNMLMKMQRH-amide,has also been reported (Phares et al., 1996). Rabbit antiseraagainst CP2 were prepared by a commercial source (ImmunoDynamics,La Jolla, CA). A synthetic peptide corresponding to the first17 residues from the amino terminal of CP2, with a cysteine substitutedfor the amino terminal phenylalanine, Cys¹-CP2[2-17], was conjugated to porcine thyroglobulin via the aminoterminal cysteine residue and injected into two rabbits for immunizationand subsequent boosts at 3 week intervals. After 10 weeks, theantisera, designated 1446 and 1447, were tested on an ELISA usingthe synthetic peptide conjugated to bovine serum albumin as theantigen. When used for immunocytology, antiserum 1446 and 1447produced similar staining, but 1447 was used routinely becauseof its lower background staining.
Immunoblot analysis of CP1 and CP2 antisera The central ganglia from two animals (~100 gm) were extracted in 20 mM trifluoroacetic acid (TFA), 28 mM 2-mercaptoethanol(2-ME) at 100°C for 10 min. Pooled extracts of the cerebral gangliaor of the remaining central ganglia minus the cerebral gangliawere run on HPLC (as described below for single neurons). Theresulting fractions were dried and brought to a volume of 10 or30 µl with 20 mM TFA, 70% CH₃CN (the volume that was used dependedon the size of the fraction). Volumes of 1-3 µl were blotted onImmobilon-P membrane (polyvinylidene difluoride, 0.45 µm poresize; Millipore, Bedford, MA) coated with 5% normal goat serum(NGS; Life Technologies, Gaithersburg, MD) in PBS. Membranes werealso blotted with synthetic CP1 or Cys¹-CP2[2-17] (0.01-100 pmol). Membranes were fixed for 4 hr in 4%paraformaldehyde vapor at 40°C and then air-dried. Membranes werewetted with methanol, washed in several changes of water, andthen washed in PBS. Nonspecific binding of antisera was blockedwith 5% NGS and 0.2% Tween 20 in PBS (0.14 M NaCl, 0.01 M phosphate,pH 7.4). Membranes were incubated with antisera against eitherCP1 (1693 diluted 1:10,000) or CP2 (1447 diluted 1:20,000) for12 hr, rinsed in several changes of 5% NGS, 0.2% Tween 20, andincubated in a 1:200 dilution of goat anti-rabbit IgG (GAR)-biotin(Vector, Burlingame, CA) in 5% NGS, 0.2% Tween 20 for 2 hr, andthen rinsed in several changes of 5% NGS, 0.2% Tween 20, followedby several changes in 0.2% Tween 20 in PBS. Membranes were incubatedin a 1:500 dilution of avidin-biotin complex conjugated to horseradishperoxidase (ABC-HRP; Vectastain Elite kit, Vector) for 1.5 hr,washed in several changes of 0.2% Tween 20 in PBS and then PBSalone, and developed in 0.025% diaminobenzidine (DAB)/0.0125%H₂O₂.
Tissue preparation and staining Whole mounts. Immunocytology of whole mounts was carried out using the methods of Longley and Longley (1986), as modifiedby Pearson and Lloyd (1989). Ganglia and peripheral tissues weredissected from immobilized animals and pinned out in a dish witha Sylgard (Corning, Corning, NY) base in a low Ca²⁺ (0.5 mM; 0.05× normal), high Mg²⁺ (110 mM; 2× normal) ASW (termed low Ca ASW). Tissue was fixedin 4% paraformaldehyde, 30% sucrose in 0.1 M phosphate buffer(PB), pH 7.4, for 4 hr at room temperature or overnight at 4°C.After fixation, the tissue was washed in PB and then in PB containing1% Triton X-100, 0.1% sodium azide for 12-24 hr. After this wash,ganglia were desheathed manually. Nonspecific binding of antibodieswas blocked by incubating the tissue in a blocking solution ofPBS with 1% Triton X-100, 0.1% sodium azide, and 5% NGS overnight.Primary and secondary antisera were diluted in this blocking solution.Anti-CP2 serum 1447 was diluted 1:10,000 for use with the ABC-HRPor 1:1000 for use with GAR IgG conjugated to a fluorophore. Fluorescentsecondary antisera GAR-aminomethylcoumarin acetate (GAR-AMCA;Jackson Labs, Bar Harbor, ME) or GAR-fluoroscein isothiocyanate(GAR-FITC; Jackson Labs) were used at a dilution of 1:100. Tissuewas mounted in 1% n-propyl gallate in a 1:6 PBS/glycerol solution,pH 8.5. When the secondary antisera were GAR-conjugated to HRP(GAR-HRP, 1:100 dilution; Jackson Labs) or GAR-biotin (1:400 dilution;Vector) followed by incubation with ABC-HRP (1:500 dilution; Vector),the tissue was incubated in 0.025% DAB (Sigma, St. Louis, MO),0.0125% H₂O₂, after which it was rinsed in PBS, dehydrated ina series of increasing concentrations of ethanol and then in 50%ethanol/50% xylenes, and finally in 100% xylenes, and mountedin DPX (Fluka, Buchs, Switzerland).

Sections. The initial handling of the tissue was the same as for whole mounts. Before the wash in Triton X-100, the tissuewas embedded in 12% gelatin in 20 mM PBS, with or without 15%sucrose. After the gelatin had set, tissue blocks were fixed overnightat 4°C in 4% paraformaldehyde, 30% sucrose. Frozen sections (20-25µM) were cut and transferred to PBS in nylon mesh-bottomed wellsfor staining. The solutions used for sections were the same asthose for whole mounts except that 0.5% Triton X-100 was used.Primary and secondary antisera were diluted in blocking solution.Sections were mounted on gelatin-coated glass slides using thethe appropriate media as described for whole mounts.

Specificity of staining was tested by the immunoblot procedure described above and by preabsorption of diluted primary antiserawith 100 µM synthetic peptide (CP1 for 1693 or Cys¹-CP2[2-16] for 1447) for 16 hr at 4°C, centrifugation at low speed,and use of the upper portion of the supernatant for immunocytology.No staining was observed for either of the peptide preabsorbedantisera. Neither preimmune antisera produced staining.
Comparison of CP1-lir and CP2-lir Whole mounts of ganglia were processed using a technique developed for double-labeling for two monoclonal primary antibodies(Wessel and McClay, 1986) modified for polyclonal rabbit antiseraand Aplysia tissue. Briefly, the first primary antiserum was applied,and after it was washed, a high concentration (1:25) of goat anti-rabbitFab fragment conjugated to either FITC or lissamine rhodaminesulfonyl chloride (LRSC; Jackson Labs) was used as the secondaryantiserum. After this tissue was washed to remove excess secondaryantiserum, the second primary antiserum was applied, followedby a wash, and then incubation with goat anti-rabbit IgG (1:100)conjugated to either AMCA or FITC. Controls for this procedurewere preabsorption of the first or second primary antiserum withthe appropriate synthetic peptide. This procedure worked wellfor whole mounts (see Fig. 4), but despite many procedural modifications,we were unable to develop conditions that produced acceptabledouble-staining in sections. Thus, for sections of ganglia orperipheral tissues, alternate sections were incubated with anti-CP1or anti-CP2 sera followed by GAR-HRP secondary antisera. For peripheraltissues, the entire buccal mass, gill, kidney, heart, genitaltract, penis complex, foot, and body wall from several small animals(1-5 gm) were sectioned. Portions of these tissues from largeranimals (50-250 gm) were also sectioned.
Fig. 4. CP1-lir and CP2-lir in whole mounts. A, Ventral surface of the cerebral ganglia showing CP2-lir using GAR(IgG)-AMCA as thesecondary antiserum. B, Same view as in A showing CP1-lir usingGAR(Fab)-FITC as the secondary antiserum. In A and B, arrowheadsindicate bilaterally symmetrical neurons in the M clusters, andarrows indicate bilaterally symmetrical neurons in rostral E clustersthat contain CP1-lir but no detectable CP2-lir. C, Medial surfaceof right pleural ganglion showing CP2-lir using GAR(Fab)-LR asthe secondary antiserum. D, Same view as in C, showing CP1-lirusing GAR(IgG)-FITC as the secondary antiserum. Medial pleuralneurons contain CP2-lir but no detectable CP1-lir. Other immunoreactiveneurons in the anterior region of the ganglion are out of theplane of focus (see Fig. 5). C-Pd, Cerebral-pedal connective;C-Pl, cerebral-pleural connective; Pd G, pedal ganglion; Pl-A,pleural-abdominal connective; SN, sensory neuron cluster. Scalebar, 200 µm.
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Interganglionic transport Transport experiments were carried out as described previously (Lloyd, 1989). Briefly, cerebral, pedal-pleural, and abdominalganglia were removed, with their connective nerves intact, andtransferred to a transport chamber. The cerebral ganglia wereisolated from the other ganglia by running the intact cerebralconnectives through a polypropylene and petroleum jelly diffusionbarrier. The cerebral ganglia were incubated for 24 hr with 0.5mCi [³⁵S]methionine (>1000 Ci/mmol; Amersham, Arlington Heights, IL)in 0.5 ml of 50% ASW (460 mM NaCl, 10 mM KCl, 11 mM CaCl₂, 55mM MgCl₂, 5 mM NaHCO₃, pH 7.8), 50% hemolymph, 0.01% glucose,25 U/ml penicillin, 25 µg/ml streptomycin, and 0.01% 2-ME. Theremaining ganglia were incubated in 150 ml of ASW with 10% L15culture medium (Sigma) modified to have the same salt compositionas ASW, 0.01% glucose, 25 U/ml penicillin, 25 µg/ml streptomycin,and 0.01% 2-ME. The labeling period was followed by a 24 hr chasewith 1 mM unlabeled methionine in the ASW, L15 medium. The pleural-abdominalconnectives, the abdominal ganglion, and the major nerves thatleave the abdominal ganglion were then extracted separately in0.5 ml of 20 mM TFA and 28 mM 2-ME, heated to 100°C for 10 min,homogenized, and centrifuged at 10,000 × g for 10 min. The supernatantwas filtered (0.45 µm, LC13, Gelman, or 0.2 µm, Microspin) andrun on HPLC (as described below for single cells).
Synthesis of CP1 and CP2 by single neurons Putative CP1- and CP2-synthesizing neurons were identified by relative size and location in living ganglia based on observationsof immunocytological staining of whole mounts. Neurons were electrophoreticallyinjected with a vital dye (1% fast green; Sigma) via an intracellularelectrode (Church and Lloyd, 1991). Newly synthesized peptideswere labeled by incubating ganglia in a 0.5 ml solution of 50%Aplysia hemolymph, 50% ASW containing 1 mM colchicine, 25 U/mlpenicillin, 25 µg/ml streptomycin, 0.1% 2-ME, and 0.5 mCi [³⁵S]methionine (Amersham) for 20 hr at room temperature (~20°C).The labeling period was followed by a 4 hr chase with 1 mM unlabeledmethionine in ASW. Individual neuronal cell bodies were dissectedusing the freeze substitution technique (Ono and McCaman, 1980)and were transferred to polypropylene microtubes containing 50µl of 20 mM TFA, 28 mM 2-ME, and 2 nmol each of synthetic buccalinA (BuA; American Peptide Co.), CP1 (BioSynthesis), CP2 (AnaSpec),FMRFamide (Bachem, Torrance, CA), myomodulin A (MmA; Peninsula,Belmont, CA), and pedal peptide (Applied Biosystems). Extractswere heated at 100°C for 10 min, cooled, 50 µl of CH₃CN was added,and the sample was filtered (0.45 µm; Microspin). The filterswere rinsed with 50 µl of 50% CH₃CN in 10 mM heptafluorobutyricacid (HFBA), and the volume was brought to 500 µl with 10 mM HFBA.Samples were analyzed by HPLC using an Aquapore RP-300 C8 column(4.6 × 220 mm; Pierce, Rockford, IL). The initial separation useda linear gradient from 15 to 50% CH₃CN in 23.3 min (counterion:10 mM HFBA). Fractions were collected, and aliquots were liquid-scintillationcounted. In some cases, aliquots of fractions were pooled, dried,and analyzed using a second gradient from 5 to 45% CH₃CN in 20min (counterion: 10 mM TFA).
Electrophysiology Ganglia were manually desheathed. Neurons were identified on the basis of published characteristics, including relative size,location, pigmentation, and synaptic connections. Identified neuronswere impaled with single microelectrodes (3-8 M $Omega$ ) containing 3M potassium acetate and 0.1% fast green. Action potential durationswere measured at the half-maximal amplitude of the first actionpotential after a long period of hyperpolarization (~60 sec) toreduce the influence of previous firing frequency. Recordingswere carried out in normal ASW (nASW), low Ca ASW (see Tissuepreparation and staining), or high Ca²⁺ (33 mM; 3× normal), high Mg²⁺ (165 mM MgCl₂; 3× normal) (termed high Ca, high Mg ASW). A minimumsuperfusion period of 1 hr was used when changing to differentASWs. Synthetic peptides were applied in a 500 µl bolus via aninjection loop into a 500 µl bath. A flow rate of ~1 ml/min wasused.
Stability of CP2 in hemolymph CP2 was incubated in hemolymph taken from a cold-anesthetized animal (15 min at 4°C) as described previously (Hall and Lloyd,1990). Briefly, radiolabeled CP2 was purified from pooled H, B,and G cluster neurons by HPLC, combined with synthetic CP2 (finaltotal concentration ~1 µM), and incubated in either previouslyboiled hemolymph or fresh hemolymph for 20 min at 22°C. Aliquotsof the samples were removed periodically and diluted into 500µl 20 mM TFA, 28 mM 2-ME containing excess unlabeled syntheticCP2 (5 nmol). This sample was centrifuge-filtered and analyzedby HPLC using the TFA gradient described above.
Injection of CP2 into freely behaving animal Each animal was weighed, isolated in a floating plastic cage within the aquarium, and observed for 15 min before injection.Overall behavior and the number of respiratory pumps (RPs) werenoted. Animals were then injected with 100-300 nmol syntheticCP2 (depending on the size of the animal) in 200-500 µl nASW andobserved for 30 min. Control animals were handled in the samemanner but were injected with only nASW.

RESULTS

CP2-like immunoreactivity in the CNS
The specificity of the antisera were determined using immunoblots of HPLC fractions from extracts of cerebral ganglia or thetotal CNS minus the cerebral ganglia. Aliquots of HPLC fractionswere blotted onto membranes and incubated with either the anti-CP1serum (1693) or the anti-CP2 serum (1447). The anti-CP1 serumdetected immunoreactivity only in the fractions in which syntheticCP1 eluted in a parallel run, and the anti-CP2 serum detectedimmunoreactivity only in the fractions in which synthetic CP2eluted in a parallel run. Immunoblots are only semiquantitative,but comparisons of the intensities of immunoreactivity from tissueswith those from synthetic peptides indicated that the paired cerebralganglia contained 1-10 pmol of CP1 or CP2, which agree with valuesestimated from the purifications: ~6 pmol CP1 and ~4 pmol CP2per paired cerebral ganglia (Phares and Lloyd, 1996; Phares etal., 1996). From the immunoblots we estimated that the remainderof the CNS contains 1-10 pmol CP1 and 0.1-1 pmol CP2. These relativevalues correlate roughly with the nature and intensity of immunocytologicalstaining that we observed (see below).

CP2-lir was found in axons and varicosities in the neuropil of all the major ganglia and in axons in every connective andperipheral nerve except the optic and buccal nerves. Positivecell bodies were localized predominantly to the cerebral ganglia.Neurons of cerebral ganglia have been divided into clusters designatedA through M (Jahan-Parwar and Fredman, 1976; Ono and McCaman,1980). On the dorsal surfaces, cell bodies containing CP2-lirwere located in the B, C, D, E, G, and H clusters (Figs. 1 and5). Another cluster of small teardrop-shaped neurons located atthe lateral margin of the cerebral-pleural connective (caudalto the D cluster and ventral to the A cluster) also containedCP2-lir. On the ventral surface of the cerebral ganglia (Figs.1 and 2), neurons containing CP2-lir were found in the B, G, andH clusters (neurons in many clusters are located on both ventraland dorsal sides of each ganglion), as well as in a medial clusterof cells immediately adjacent to and on both sides of the commissure,which we have designated the N cluster, extending the establishednomenclature for cerebral neuronal clusters (Jahan-Parwar andFredman, 1976). CP2-lir was also observed in several cell bodiesin the anterior region of each pleural ganglion (Fig. 5). In thebuccal ganglion, immunoreactive fibers were found predominantlyin the lateral region of the neuropil and surrounding the cellbodies and initial segments and cell bodies of several small neurons(Fig. 3A). In addition, CP2-lir was observed in a cluster of verysmall neurons on the caudal surface of each buccal ganglion lateralto where the esophageal nerve exits the ganglion (not shown).Three clusters of neurons in the abdominal ganglion were alsoimmunoreactive for CP2. One cluster was located in the left hemiganglionat the lateral margin of the dorsal surface. Another cluster wasin the right lower quadrant between identified neurons R2 andR15 (Fig. 3B). Most of these cells were below the surface layerof neurons, just above the neuropil. The third cluster is locatedat the lateral margin of the right upper quadrant. CP2-lir wasalso observed in varicose axons surrounding the bag cells (Fig.3C). In the pedal ganglia, no cell bodies contained CP2-lir, butmany immunoreactive fibers and varicosities were found in theneuropil and peripheral nerves.
Fig. 1. Whole mounts showing the locations of neurons containing CP2-lir in the cerebral ganglia visualized using GAR-biotin and ABC-HRPas viewed from the ventral surface. A, Dorsal surface. The locationof the H cluster is indicated (arrow). B, Diagram of the dorsalsurface illustrating the positions of the major neuronal clusters.C, Ventral surface. The labels for G, N, and B clusters are positionedbetween these bilateral clusters. Immunoreactive neuronal cellbodies are located in a number of neuronal clusters on both sidesof the ganglia (see text). Photomicrographs and diagram are asviewed from the ventral side, so right and left ganglia appearreversed for A and B. Neuronal clusters are designated as in Jahan-Parwarand Fredman (1976), except the N cluster (see text). AT, Anteriortentacular nerve; C-B, cerebral-buccal connective; C-Pd, cerebral-pedalconnective; C-Pl, cerebral-pleural connective; PT, posterior tentacularnerve. Scale bar (shown in C): 200 µm (applies to A-C).
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Fig. 5. Schematic diagrams of the location of neuronal cell bodies containing CP1-lir or CP2-lir, or both CP1-lir and CP2-lir in selectedganglia. A, Dorsal surface of the cerebral ganglia. B, Ventralsurface of the cerebral ganglia. Arrows indicate the positionsof isolated individual neurons in the M clusters that containedCP1-lir only. C, Medial surface of the right pleural ganglion.Nerves from the cerebral ganglia are designated as in Fredmanand Jahan-Parwar (1976). AC, Anterior cluster; AT, anterior tentacularnerve; C-B, cerebral-buccal connective; C-Pd, cerebral-pedal connective;C-Pl, cerebral-pleural connective; LL, lower lip nerve; PC, posteriorcluster; Pl-A, pleural-abdominal connective; Pl-Pd, pleural-pedalconnective; PT, posterior tentacular nerve; SN, sensory neuroncluster; UL, upper lip nerve. Scale bar, 200 µm (applies to A-C).
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Fig. 2. Section through the cerebral ganglia near ventral surface showing CP2-lir in the cytoplasm of neuronal cell bodies in theregions of the B, G, and H clusters visualized using GAR-biotinand ABC-HRP. Large immunoreactive fibers extend from these clustersand extend across the commissure (com) and leave the ganglionin the cerebral-pedal (C-Pd) and cerebral-pleural (C-Pl) connectives.Smaller fibers with varicosities are found throughout the neuropil.AT, Anterior tentacular nerve; E, E cluster; UL, upper lip nerve.Photomicrograph is viewed from the ventral side, so right andleft ganglia appear reversed. Scale bar, 200 µm.
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Fig. 3. CP2-lir in the other ganglia. A, Immunoreactive fibers and varicosities surrounding the axon hillock and cell body of a neuronin the buccal ganglia visualized using GAR-biotin and ABC-HRP.Scale bar, 100 µm. B, Two immunoreactive neurons in the rightcaudal quadrant of the abdominal ganglion visualized using GAR-FITC.These neurons are part of a cluster of ~10 immunoreactive neuronsscattered between identified neurons R2 and R15. The neuropilto the left of the cell bodies contains immunoreactive smoothand varicose fibers. Scale bar, 50 µm. C, Immunoreactive varicosefibers in the bag cell cluster (BCC) and the pleural-abdominalconnective (Pl-A) visualized using GAR-FITC. Scale bar, 50 µm.
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Colocalization of CP1-lir and CP2-lir in the CNS
The localization of CP2-lir in the cerebral ganglia was similar to that observed previously for CP1-lir (Phares and Lloyd,1996). Figure 4 shows the ventral surface of cerebral gangliathat were double-stained for CP1-lir and CP2-lir. Many neuronswere immunoreactive for both peptides, including those of theB, G, H, and N clusters; however, several neurons contained onlyCP1-lir or CP2-lir but not both. For example, neurons containingonly CP1-lir were found in the bilaterally symmetrical rostralE and M clusters of the cerebral ganglion. On the dorsal surface,many of the smaller neurons seemed to contain only CP1-lir orCP2-lir (Fig. 5). CP2-lir, but not CP1-lir, was observed in anasymmetric cluster of small neurons in the right pleural ganglion(Fig. 4). These neurons were located between the pleural sensoryneurons and the posterior cluster on the medial surface of theganglion (Kehoe, 1972). Neurons in the anterior cluster containedeither CP1-lir or CP2-lir or both (Fig. 5). In other ganglia,CP1-lir and CP2-lir were found in different populations. For example,the bilateral clusters of pedal neurons that were immunoreactivefor CP1 (Phares and Lloyd, 1996) did not contain CP2-lir.

In the periphery, CP1-lir and CP2-lir were found in fibers in the gill, foot, body wall, and genital tract, whereas only fiberscontaining CP2-lir were observed in the penis. Neither CP1-lirnor CP2-lir was observed in the heart, kidney, or buccal mass.Because many of the peripheral tissues innervated by the abdominalganglion contained immunoreactive fibers and because very fewneurons in this ganglion contained CP1-lir and CP2-lir, we investigatedwhether some of the CP1 and CP2 in these tissues might be synthesizedin the cerebral ganglia and transported to the abdominal ganglionand then out peripheral nerves. To test for this, cerebral gangliawere incubated in [³⁵S]methionine, and the relative amounts of labeled CP1 and CP2transported to the pleural-abdominal connectives, abdominal ganglion,and peripheral nerves leaving the abdominal ganglion were determined.Although most of the radiolabeled CP1 and CP2 was associated withthe connectives and the abdominal ganglion (76.4 ± 6.3% totaltransported CP1 and 60.1 ± 7.9% total transported CP2; mean ±SEM; n = 7), labeled CP1 and CP2 were also detected in the peripheralnerves. Most of the labeled CP1 and CP2 were found in the branchialnerve (15.3 ± 3.7% of CP1 and 26.0 ± 5.2% of CP2). Occasionally,labeled CP1 or CP2 was also detected in the siphon or genitalnerve, although the level of this transport varied between experiments.Labeled CP1 or CP2 was not recovered from the pericardial nerve,an observation consistent with the lack of immunoreactivity inthe heart and kidney, two of the major tissues innervated by thisnerve (Kandel, 1979).

Synthesis of CP1 and CP2 by single neurons
We analyzed peptide synthesis in individual neurons as an independent method for determining whether CP1 and CP2 were colocalizedin neuronal cell bodies. Intracellular recordings were made fromneurons in the B, G, and H clusters of the cerebral ganglia tocharacterize their spontaneous activity, action potential durations,and in some cases, their synaptic connections. The neurons werethen stained with fast green injected via the intracellular electrodeand incubated with [³⁵S]methionine. Individual cell bodies were then dissected and extracted,and labeled peptides were analyzed by HPLC using HFBA as the counterion.Examples of HPLC of extracts from individual neurons from eachof the clusters are shown in Figure 6, and the content of radiolabeledpeptide corrected for the number of methionine residues in eachpeptide is summarized in Figure 8. For the neurons listed below,the labeled CP1 and CP2 peaks from the first HPLC runs continuedto coelute with their respective synthetic peptides when aliquotsof the peaks were analyzed by a second HPLC gradient using a differentcounterion (TFA).
Fig. 6. Examples of HPLC of extracts from individual neurons dissected from clusters in the cerebral ganglia that were positive forCP1-lir and CP2-lir. Cell extracts were run with HFBA as the counterion.Dashed lines indicate the retention times of synthetic CP1 andCP2 as monitored by absorbance. For each neuron, the identitiesof CP1 and CP2 were confirmed by running aliquots from these peakson HPLC with TFA as a counterion. Arrows represent the retentiontimes for synthetic BuA in the H neuron profile and syntheticMmA in the N neuron profile (see text). Aliquots of the peak thatseems to coelute with BuA in the H neuron profile on this gradientdid not coelute with BuA when run with TFA as a counterion. Inthis and the next figure, unincorporated [³⁵S]methionine is the predominant component of the broad peak, withbrief retention time (0-3 min) that in some cases is truncated(i.e., N Neuron).
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Fig. 8. Radiolabeled peptide content in neurons from selected clusters of the cerebral ganglia. Incorporation into peptides is representedas the percentage of total radioactivity recovered from HPLC runsto compensate for the wide range of sizes of the neuronal cellbodies. In addition, the radioactivity associated with CP2 wasdivided by 3, because this peptide contains three methionine residues,whereas CP1 and FMRFamide each contain one methionine residue.Values are mean ± SEM, with n = 9 for Bb, 9 for G, 10 for H, and4 for Bn neurons.
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B cluster neurons
Neurons in the B clusters of the cerebral ganglia can be divided into two major subpopulations on the basis of location, morphology,the nature of their synaptic connections, and biophysical characteristics(Teyke et al., 1989). Bn neurons have narrow (rapid) action potentials,receive input from A neurons and other Bn neurons, and are locatedpredominantly on the dorsal sides of the ganglia, whereas Bb neuronshave broad action potentials, do not receive input from eitherA neurons or other B neurons, and are located predominantly onthe medial ventral region of the ganglia (Fig. 5). On the basisof the location of immunoreactive cell bodies, we predicted thatBb neurons would synthesize CP1 and CP2, whereas Bn neurons wouldnot. Indeed, all Bb neurons that were analyzed (9 of 9) and noBn neurons (0 of 4) synthesized CP1 and CP2. Action potentialdurations at half-maximal amplitude were 8.2 ± 0.9 msec (mean± SEM; n = 9) for Bb neurons and 2.8 ± 0.7 msec (n = 4) for Bnneurons. When the levels of synthesis for the two peptides inBb neurons were compared, it was found that these neurons producedabout half as much CP1 as they did CP2 (Fig. 8). We also determinedthat all Bn neurons that were analyzed (4 of 4) synthesized anotherneuropeptide, FMRFamide (Fig. 7); thus, the division of the Bcluster neurons into Bb and Bn populations is also supported bythe nature of their neuropeptide expression.
Fig. 7. Examples of HPLC of extracts from individual neurons dissected from the cerebral Bn cluster, which was not immunoreactivefor CP1 or CP2, and the asymmetric right pleural ganglion cluster,which was positive for CP2-lir but not CP1. Cell extracts wererun with HFBA as a counterion, as in Figure 6. Dashed lines indicatethe retention times of synthetic CP1, FMRFamide (FMRFa), and CP2as monitored by absorbance. The identities of FMRFamide and CP2were confirmed by running aliquots from these peaks on HPLC withTFA as a counterion.
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G cluster neurons
Many of the G cluster neurons that were analyzed (9 of 19) synthesized both CP1 and CP2 (Fig. 6). These neurons were foundin the medial region of the cluster, predominantly on the ventralsurface (Fig. 5). Like the Bb neurons, these G cluster neuronssynthesized about half as much CP1 as CP2 (Fig. 8). These neuronswere either silent or spontaneously active at low rates ( $<=$ 1 Hz)in the isolated cerebral ganglia, and they had broad action potentials(duration at half amplitude = 9.8 ± 1.5 msec; n = 9). The neuronsthat did not synthesize CP1 or CP2 usually were located more laterallyin the cluster, did not seem to synthesize significant amountsof any methionine-containing peptides, and had narrower actionpotentials (4.0 ± 0.2 msec; n = 10).

H cluster neurons
We have shown previously that pooled H cluster neurons synthesized CP1 and an unidentified peptide using a gradient that wouldnot elute CP2 (Phares and Lloyd, 1996). In the present study,we found that all H cluster neurons that were analyzed (10 of10) synthesized CP1 and CP2 as well as small amounts of the unidentifiedpeptide (Fig. 6). It seems likely that all of the neurons in thiscluster synthesize at least the three peptides. In contrast toBb and G cluster neurons that synthesized CP1 and CP2, H clusterneurons synthesized more CP1 than CP2 (Fig. 8). Immunocytologicalevidence suggested that H cluster neurons also contained BuA (Milleret al., 1992), which contains a methionine residue and thus shouldbe detected by our labeling procedure. Although the unidentifiedpeptide elutes very close to synthetic BuA on the first gradient(counterion: HFBA), no labeled BuA was detected on a second gradientusing a different counterion (TFA; n = 4).

Other neurons
Some N cluster neurons (2 of 6) did synthesize low levels of CP1 and CP2 (Fig. 6). The finding that some neurons in the Ncluster did not seem to synthesize CP1 and CP2 was unexpected,because all neurons in this cluster were positive for CP1-lirand CP2-lir. Our inability to detect synthesis of CP1 or CP2 insome of the N-cluster neurons could be attributable to their smallsizes. Many of these neurons had small diameters and were flattenedrather than spherical, thereby further reducing their volume.It is also possible that N-cluster neurons synthesized the peptidesat lower specific rates than neurons from the other cerebral clustersthat were analyzed.

Although the Bb, medial G, and H neurons described above synthesized both CP1 and CP2, our immunocytological results indicatedthat other neurons synthesized only CP1 or CP2. These neuronsare either isolated or very small, so our attempts to measurepeptide synthesis in them have met with limited success. We didfind, however, a single example of a neuron in the M cluster thatseemed to synthesize only CP1 (data not shown), consistent withour observation that one neuron in each M cluster contained CP1-lirbut no CP2-lir (Fig. 4). Also, neurons from the asymmetric clusterfound in the right pleural ganglion synthesized CP2 but not CP1(10 of 19 analyzed; Fig. 7). This agrees with results from immunocytology,which showed that neurons in this region contained only CP2-lir(Fig. 4). Of the 10 pleural neurons that synthesized CP2, sixalso synthesized FMRFamide, and four synthesized an unidentifiedmethionine-containing peptide. Of the pleural neurons that didnot synthesize CP2, all synthesized FMRFamide (9 of 9). Theseneurons were located posterior and dorsal to the CP2 cluster.

We wished to determine which of the cerebral clusters described above contained neurons that were likely to synthesize CP1and CP2 and transport them to the abdominal ganglion. To do this,we identified neurons in clusters in the cerebral ganglia on thebasis of location and electrophysiological properties that wehad previously found to synthesize CP1 and CP2, and we stimulatedthe pleural-abdominal connective with a suction electrode to determinewhether these neurons sent an axon into the connective. The pleural-abdominalconnective is the major neural connection between head ganglia,including the cerebral ganglia and the abdominal ganglion. Antidromicspikes were observed in most of the Bb neurons (15 of 26), manyof the medial G neurons (6 of 15), and none of the H neurons (0of 15) tested. It seems most likely that transport of CP1 andCP2 is occurring in the axons of the Bb and G neurons, althoughthe possibility of blockade of antidromic spike conduction ataxon branches of H neurons cannot be excluded.

Electrophysiological responses of neurons in the buccal and abdominal ganglia to CP2
Neuronal cell bodies that were densely innervated with varicosities containing CP2-lir were particularly prominent in thebuccal and abdominal ganglia (Fig. 3A). Thus, it seemed most likelythat neurons in these ganglia would respond to CP2 applied viathe bath. As reported previously, we have not yet found any biologicalactivity for CP1 on central neurons (Phares and Lloyd, 1996);however, a number of identified neurons in the buccal and abdominalganglia were depolarized by the application of synthetic CP2.Specifically, we tested the effects of CP2 on neurons that couldbe identified by a combination of size, location, appearance,the nature of their spontaneous activity, and synaptic connectionswith other identified neurons.

Buccal ganglia
The buccal ganglia contain many of the neurons that mediate consummatory feeding behaviors, i.e., biting, swallowing, andrejection (Kupfermann, 1974). In nASW, bolus applications of CP2to the isolated buccal ganglia elicited buccal motor program (BMP)-likerhythmic activity in many of the identified motor neurons in theventral cluster (Fig. 9A). These effects did not persist in lowCa ASW, which inhibits chemical synaptic transmission, suggestingthat they were not direct effects on these neurons. The relativetiming of bursts in these neurons is useful in identifying thenature of the BMPs (Cropper et al., 1990; Morton and Chiel, 1993;Church and Lloyd, 1994). Two basic BMPs have been described: ingestiveBMPs (iBMPs) and egestive BMPs (eBMPs). In the patterned activityapplication of CP2 that was caused, B4 and B7 fired in phase witheach other, a characteristic of eBMPs (Fig. 9A). Bursts in B4and B5 were weaker than in either type of BMP; however, the patternobserved in B38 was more similar to that observed during a weakiBMP. Also, application of CP2 caused bursts of action potentialsin neurons such as B1, B2, and B13, which do fire during iBMPsbut not during eBMPs. Thus, application of CP2 evoked patternedactivity that had some characteristics of an iBMP, the patternbeing similar but not identical to iBMPs evoked by stimulationof cerebral-to-buccal interneuron 2 (Rosen et al., 1991; Churchand Lloyd, 1994). Of the many neurons recorded from in the buccalganglia, we found only one identified neuron that seemed to responddirectly to CP2. This neuron, termed B41 (Ono, 1989), depolarizedin response to CP2, and this effect persisted in low Ca ASW (Fig.9B). Intracellular stimulation of B41 produced synaptic potentialsin many other neurons but did not elicit a BMP; thus CP2 mustalso act on other premotor neurons in the buccal ganglia to initiatethe BMP.
Fig. 9. Responses of neurons in the buccal ganglia to bolus applications of CP2. A, Bolus application of 10⁵ M CP2 in nASW evokes rhythmic inputs into three ventral clustermotor neurons (B38, B8, and B7) and multifunctional neuron B4.B, Depolarization of B41 by bolus applications of CP2 at the indicatedconcentrations. B41 was identified by relative size and positionand its synaptic connections to B4 and B13 (Ono, 1989). This experimentwas performed in low Ca ASW to suppress chemical synaptic transmission.Similar results were obtained from B41 neurons in other preparations(7 of 7 analyzed).
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Abdominal ganglion
In nASW, many neurons in the isolated abdominal ganglion did respond to the application of CP2 with a change in their ongoingactivity. When CP2 was applied in low Ca ASW, however, the responseswere no longer present, suggesting that they were indirect. InRB cells recorded in nASW, CP2 elicited a series of hyperpolarizingresponses that seemed to be attributable to bursts of action potentialsin an inhibitory neuron presynaptic to the RB neurons. This inputseemed similar to that produced by R20 neurons, which are a pairof very similar electrically coupled neurons that modulate respiratorypumping (Alevizos et al., 1989). Accordingly, we recorded fromR20 neurons and found that CP2 produced a dose-dependent depolarization(11 of 11 neurons analyzed). In nASW, the depolarization was oftenaccompanied by a volley of IPSPs (Fig. 10). In low Ca ASW, CP2continued to evoke a depolarization of similar amplitude and timecourse, suggesting that it was a direct action on R20 neurons,whereas the compound IPSP was no longer observed, suggesting thatit was an indirect effect of CP2 on other neurons presynapticto the R20 neurons. Similar responses, including the direct depolarizationand indirect recruitment of a compound PSP, were observed in otherneurons in the abdominal ganglion, some of which were in the respiratorypumping circuit, including the R25 (3 of 3), RG (15 of 15), LD(3 of 3), and L7 (5 of 5) neurons (Frazier et al., 1967; Koesterand Kandel, 1977; Alevizos et al., 1989; Koester, 1989). In multifunctionneuron L7, the indirect input evoked by CP2 was an excitatory-inhibitoryPSP that was coincident with the IPSP recorded in other neurons.Other neurons that are in the respiratory pumping circuit, suchas R15 (4 of 4) and L11 (4 of 4), seemed to receive only the indirectcompound IPSP and did not respond directly to CP2. In addition,neuron L5 seemed to be depolarized directly by CP2 (4 of 4), butit did not receive any indirect input. Thus, CP2 elicited variousresponses when applied in nASW but either no response or a depolarizationwhen applied in low Ca ASW.
Fig. 10. Responses of neurons in the abdominal ganglion to bolus applications of CP2. A, Depolarization of R20 by bolus applicationof CP2 at the indicated concentrations. R20 was identified byrelative size and position, pigmentation, pronounced spike broadeningexhibited during repetitive firing, synaptic connections to RBor RG neurons, and the nature of its responses to applicationsof FMRFamide and myomodulin (Alevizos et al., 1989). This experimentwas performed in nASW. Note that, in addition to a dose-dependentdepolarization of R20, the higher doses of CP2 also recruiteda large hyperpolarizing response that was made up of a numberof individual IPSPs when observed at a faster time base. B, Depolarizationof R20 by bolus application of CP2 at the indicated concentrations.This experiment was performed in low Ca ASW to suppress chemicalsynaptic transmission. CP2 continued to cause a dose-dependentdepolarization similar in amplitude and time course to those observedin A, but no compound IPSPs were recruited. Records in A and Bare from the same neuron. Similar results were obtained from R20neurons in other preparations (11 of 11 analyzed).
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Injection of CP2 into intact animals
We were interested in determining the behavioral effects of injected CP2. First, we tested whether CP2 was stable in Aplysiahemolymph, which rapidly degrades a number of neuropeptides (Halland Lloyd, 1990; Squire et al., 1991; Rothman et al., 1992). Combinedradiolabeled and synthetic CP2 (total concentration ~1 µM) wereincubated with either freshly collected hemolymph or previouslyboiled hemolymph as a control, and aliquots were analyzed by HPLC.CP2 was stable in boiled hemolymph. It was also quite stable infresh hemolymph: only 2.5% was broken down after a 10 min incubationand 5.2% after 20 min, suggesting that injected CP2 might remainactive for some time.

CP2 was injected into the hemocoel of four freely behaving animals in quantities that would reach a final concentration of~3 µM if distributed evenly in the animal. This concentrationwas chosen because it reliably elicited responses in neurons inisolated ganglia (see above). Control animals were injected withnASW only. Four consistent changes in behavior were observed inthe animals injected with CP2. Consistent with the results fromthe electrophysiological studies, there was a marked increasein the rate of respiratory pumping. No RPs were observed in controlanimals before or after injection; however, animals given CP2showed a marked increase in the frequency of RPs that peaked 15-20min after the injection (Fig. 11). This is similar to the timecourse for the initiation of egg-laying behavior in animals injectedwith synthetic egg-laying hormone (Bernheim and Mayeri, 1995).The earliest observable effects of CP2 were an increase in rapidlocomotion, a loss in the ability of the medial and posteriorregions of the foot to attach to the substrate, and uncoordinatedcontractions of the parapodia. Consummatory feeding behaviorssuch as biting were not observed in any of the animals injectedwith CP2, although it is possible that other ingestive behaviors(e.g., swallowing) or small movements of the buccal mass occurredbut were not visible.
Fig. 11. RP rates were increased by injections of synthetic CP2 into freely behaving animals. Animals (four pairs) were observed for15 min, injected with either nASW (control) or nASW containingCP2, and observed for an additional 30 min. No RPs were observedin the control animals before or after injections. The figureshows the mean RP rate (RP/hr) in 5 min periods before and afterthe CP2 injections. (* indicates significant differences fromthe control group, using t test and 0.05 significance levels.)
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DISCUSSION
CP2-lir was found in approximately 200 neurons located predominantly in the cerebral ganglia. Less numerous, smaller immunoreactiveneurons were also found in the abdominal, pleural, and buccalganglia, but none were observed in the pedal ganglia. The resultsfrom immunoblots and labeling experiments suggestd that at leastmost of this immunoreactivity represents authentic CP2. Resultsfrom immunocytological and biochemical procedures indicate thatCP2 is colocalized with CP1 in neurons of the Bb cluster, themedial ventral G cluster, and the H cluster in the cerebral ganglia;however, the colocalization of CP1 and CP2 is a complex phenomenon.The relative content of radiolabeled CP1 and CP2 varies betweenneurons from different clusters, and some neurons contain onlyCP1 or CP2 but not both. It is possible that a single mRNA orprecursor protein for CP1 and CP2 is processed differently indifferent neurons or that the expression of separate genes givesrise to precursor proteins for CP1 or CP2. Currently, we haveno way to distinguish between these possibilities. We also observedthe coexpression of CP2 and FMRFamide in an asymmetric clusterof small neurons in the right pleural ganglion. This cluster wasnot described in previous studies of the distribution of FMRFamide-likeimmunoreactivity in the pleural ganglia (Soinila and Mpitsos,1991; Small et al., 1992). In addition to the overlap with CP1-lirin the cerebral ganglion, the location of neurons that containedCP2-lir was distinct from that reported for other peptides inAplysia, with two exceptions: neurons in the cerebral H clustercontain buccalin-like immunoreactivity (Miller et al., 1992),and neurons in the newly designated cerebral N cluster containmyomodulin-like immunoreactivity (Miller et al., 1991). We foundno evidence, however, for buccalin synthesis in the entire H cluster(Phares and Lloyd, 1996) or in this study in individual H clusterneurons. It is unlikely that the antiserum directed against buccalinis binding to CP1 and CP2, because there is little sequence similarityamong the peptides, and other neurons that contain CP1-lir andCP2-lir do not contain buccalin-like immunoreactivity. It is possiblethat the buccalin antiserum binds to the unidentified methionine-containingpeptide we found to be synthesized in H cluster neurons. The lowlevels of synthesis in N cluster neurons made it difficult todetermine whether they might synthesize myomodulin in additionto CP1 and CP2.

CP1 and CP2 were identified originally because they were the major methionine-labeled peptides transported from the cerebralganglia to the abdominal ganglion. Our results suggest that neuronsfrom the Bb and medial G clusters are the most likely candidatesfor the neurons that synthesize CP1 and CP2 and transport themalong axons from the cerebral ganglia to the abdominal ganglion.These results agree with those of a more general study in whichantidromic responses were recorded from neurons in a number ofclusters in the cerebral ganglia while stimulating the pleural-abdominalconnective (Jahan-Parwar and Fredman, 1976). Neurons in theseclusters are also labeled by backfills of the pleural-abdominalconnective (Fredman, 1987; Ferguson et al., 1989) or retrograde-labelingfrom the abdominal ganglion with fluorescent dyes (Hawkins, 1989;McPherson and Blankenship, 1991). Bb neurons are putative modulatoryneurons that send axons into both the cerebral-pedal and the cerebral-pleuralconnectives and out various peripheral nerves of the pleural andpedal ganglia to innervate the body wall and foot (Teyke et al.,1989). They may also innervate the body wall in the mantle regionvia the peripheral nerves of the abdominal ganglion. Bn and Bbneurons were differentiated originally on the basis of physiologicaland morphological characteristics (Teyke et al., 1989). They nowcan also be differentiated on the basis of their expression ofneuropeptides: all Bb neurons that were analyzed synthesized CP1and CP2, whereas all Bn neurons synthesized FMRFamide. Neuronscontaining FMRFamide-like immunoreactivity have been localizedto the region of the B cluster occupied predominantly by Bn neurons(Soinila and Mpitsos, 1991). Also, it is likely that some Bn neuronssend axons into the pleural-abdominal connective (Jahan-Parwarand Fredman, 1976; Mackey et al., 1989). Thus, Bn neurons mayaccount for some of the FMRFamide found to be transported fromthe cerebral ganglion to the abdominal ganglia and perhaps tothe pedal and pleural ganglia as well (Lloyd, 1989).

In the B and G clusters, where CP1- and CP2-containing neurons were intermingled with neurons that do not express these peptides,we have attempted to make it possible for others studying neuronsin these clusters to be able to determine whether a neuron expressedCP1 and CP2 from its electrophysiological properties alone. Fortunately,this turned out to be relatively straightforward, because bimodaldistribution of action potential durations correlated accuratelywith the expression of CP1 and CP2. In both clusters, neuronswith action potentials of relatively long duration expressed CP1and CP2, and neurons with action potentials of relatively shortduration did not. The long duration action potentials, however,were not simply correlated with peptide expression, because Bnneurons expressed FMRFamide at levels comparable to the expressionof CP1 and CP2 in Bb neurons.

It has been suggested that the H cluster may be homologous to the the asymmetric region of the right mesocerebrum of the pulmonatesnail, Helix pulmonata, and the anterior lobe of the right cerebralganglion of Lymnaea stagnalis (Miller et al., 1991). Neurons inthese regions seem to innervate the penis (Chase, 1986; Crolland van Minnen, 1992; Smit et al., 1992; Li and Chase, 1995);however, few H cluster neurons send axons into the pathways fromthe cerebral ganglia to the penis (Jahan-Parwar and Fredman, 1976).Results presented here suggest that H-cluster neurons do not representa major input to the penis, because these neurons actually synthesizemore CP1 than CP2, but only CP2-lir was observed in this tissue.

Electrophysiological results suggest that neurons that synthesize CP2 may be involved in the generation of behaviors in thebuccal and abdominal ganglia. In the buccal ganglia, CP2 seemedto activate neurons that initiate patterned activity in ventralcluster motor neurons. It is possible that CP2-containing cerebralneurons may be the normal source of CP2 in the buccal ganglia.It has been shown that the presence of the cerebral ganglia isnecessary for biting, an ingestive behavior (Kupfermann, 1974).Neurons containing CP2-lir are present in both the E and G clustersof the cerebral ganglia. Neurons in these clusters modulate buccalmotor programs and feeding behaviors (Weiss et al., 1978; 1986;Chiel et al., 1986, 1988; Rosen et al., 1991), and several axonscontaining CP2-lir were observed in the cerebral-buccal connective.

In the abdominal ganglion, CP2 directly depolarized both R20 and R25 neurons, two neuronal groups that participate in theinitiation or modulation of respiratory pumping (Alevizos et al.,1989; Koester, 1989). The cerebral ganglia do seem to play a rolein the regulation respiratory pumping, because lesioning themreduces the increase in pumping rate produced by elevated CO₂levels (Levy and Susswein, 1993). Unfortunately, we have not yetidentified neurons in the cerebral ganglia that synthesize CP2and are presynaptic to the R20 or R25 neurons.

Freely behaving animals injected with CP2 increased their respiratory pumping rate consistent with the effects of the peptideon identified neurons in the abdominal ganglion. Because CP2 wasstable in hemolymph and is similar in size to several known neurohormonesin Aplysia (Chui et al., 1979; Campanelli and Scheller, 1987;Weiss et al., 1989; Nagle et al., 1990), it may also act as aneurohormone. Injected CP2 may also act on neurons in the cerebraland pedal ganglia that initiate or mediate locomotion or parapodialmovements.

We have identified a new peptidergic transmitter that seems to be used by a large number of neurons in the cerebral gangliaand has potent excitatory effects on many neurons in other gangliain Aplysia. These results suggest that using fast axonal transportof labeled peptides as an assay for identifying transmitter-likepeptides is a powerful procedure that may have wide applicationto other neural systems in Aplysia and other animals.

FOOTNOTES

Received Aug. 26, 1996; revised Sept. 23, 1996; accepted Sept. 26, 1996.

This work was supported by National Institutes of Health Training Grant T32-GM-07839 to G.A.P., National Science FoundationGrant IBN-9418815, and a grant from the Brain Research Foundationto P.E.L. We thank Lyle Fox for critically reading this manuscript.

Correspondence should be addressed to Philip E. Lloyd, Committee on Neurobiology, University of Chicago, 947 East 58th Street,Chicago, IL 60637.

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