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Previous Article | Next Article
Volume 16, Number 24, Issue of December 15, 1996 pp. 8092-8104
Copyright ©1996 Society for NeuroscienceCostorage and Corelease of Modulatory Peptide Cotransmitters with Partially Antagonistic Actions on the Accessory Radula Closer Muscle of Aplysia californica
F. S. Vilim1, D. A. Price2, W. Lesser2, I. Kupfermann1, and K. R. Weiss3 1 Center for Neurobiology and Behavior, College of Physicians and Surgeons, Columbia University, New York, New York 10032, 2 C. V. Whitney Laboratories, University of Florida, St. Augustine, Florida 32086, and 3 Department of Physiology and Biophysics, Mount Sinai School of Medicine, New York, New York 10029
ABSTRACT
Many neurons that contain a classical neurotransmitter also contain modulatory peptides, but it has been difficult to establish unequivocally that these peptides are functional cotransmitters. Here, we provide evidence for functional cotransmission in a neuromuscular system of Aplysia. Using immunocytochemical techniques, we localize members of two peptide families, the small cardioactive peptides (SCPs) and the buccalins (BUCs), to a single subset of dense-core vesicles in the terminals of the cholinergic motorneuron B15. We describe a new preparation and method for the direct detection of released peptides and show that the SCPs and BUCs are released when neuron B15 is intracellularly stimulated. Consistent with their subcellular localization, the SCPs and BUCs are released in a stoichiometric ratio that is constant across conditions that change the absolute amount of peptides released. Peptide release is calcium-dependent but does not require muscle contractions. Thus, the release cannot be attributed to a displacement of peptides that may be present in the extracellular space. In previous studies, we characterized the physiological firing patterns of neuron B15. Here, we simulate these firing patterns and show that peptide release occurs. Additionally, we find that significant quantities of material are released under behaviorally relevant conditions. We find that concentrations of released peptides in the muscle are in the concentration range in which exogenously applied peptides exert characterized modulatory actions on muscle contractions. Together, our findings provide strong support for the hypothesis that peptides contained in neuron B15 are functional cotransmitters.
Key words: neuropeptides; dense-core vesicles; peptide release; Aplysia; cotransmission; EM immunocytochemistry; motor neuron; modulation
INTRODUCTION
When several putative transmitters are found in a single neuron, it is easy to assume that they function as cotransmitters. This supposition, however, has been difficult to verify. A recent review of cotransmission (Kupfermann, 1991
) concluded that there was no definitive evidence that cotransmission occurs under normal physiological conditions. In general, the greatest obstacle to establishing functional cotransmission has been the difficulty in demonstrating that putative cotransmitters are released when neurons fire in physiological patterns.
To overcome difficulties in the study of cotransmission, simpler, more experimentally advantageous model systems were developed. One such system consists of the accessory radula closer (ARC) muscle and its cholinergic motorneurons, B15 and B16. B15 and B16 synthesize peptides that potentiate contraction size and relaxation rate. B15 synthesizes (Cropper et al., 1987a
Studies of peptide release in the ARC (Whim and Lloyd, 1989
Additionally, previous experiments have sought only to demonstrate the release of the peptides that exert potentiating actions. Because B15 also synthesizes the BUCs, fundamental questions concerning the physiological consequences of peptide release in the ARC remain unanswered. Thus, are the BUCs and the SCPs packaged in the same vesicles and coreleased, or are they packaged in different vesicles and differentially released (Sossin et al., 1989
MATERIALS AND METHODS
Animals. Specimens of Aplysia californica were obtained from Marinus. The animals were maintained at 14-16°C on a 12 hr light/dark cycle and fed every 3 d. Animals in the range of 50-100 gm were used for the morphology experiments, and animals in the range of 300-600 gm were used for release experiments. Isotonic MgCl2 (25-50% body weight) was used to immobilize the animals, and all stages of the dissection were carried out in the animals' own hemolymph containing the added MgCl2.
Backfills. A unilateral ARC preparation was pinned out on SYLGARD (Dow Corning, Corning, NY) in a 3-inch-deep dish. A 3-inch-deep subchamber was sealed around the distal portion of the ARC with silicone grease. The space outside the subchamber was filled almost to the top with L-15 (adjusted to Aplysia salinity and buffered with 10 mM HEPES to pH 7.6). The fluid inside the subchamber was evacuated, and the viability of the seal was evaluated. If the seal was adequate, the filling solution (1 M CoCl2 or 1 M NiCl2) was added to the subchamber in amounts sufficient to completely submerge the ARC (~100 µl). The hydrostatic back pressure prevented the nonspecific diffusion of filling solution. The preparation was then placed at 4°C, and the filling solution was changed daily. After 2-3 d, the filling solution in the subchamber was washed out with several changes of artificial seawater (ASW), and the preparation was pinned out in a smaller dish for developing. The preparation was developed by the addition of a one-tenth volume of saturated dithio-oximide in 95% ethanol, which produces a blue-black precipitate with NiCl2 and a red-brown precipitate with CoCl2 (Quicke and Brace, 1979
Antibodies. The rabbit antibody to SCPb used for immunocytochemistry was a kind gift from Dr. Richard Scheller (Stanford University, Stanford, CA). The rabbit antibody to SCPb used for radioimmunoassay (RIA) was a kind gift from Dr. H. R. Morris (Imperial College). The rabbit antibody to buccalin used for immunocytochemistry and RIA was raised against BUCa coupled to bovine serum albumin (BSA). The rat antibody to SCPb used for immunocytochemistry was raised against peptide coupled to bovine thyroglobulin (BTG). The peptides were coupled to the carrier protein with 1-ethyl-3-(3-dimethylaminopropyl)- carbodiimide (EDC). The rabbit buccalin antibodies were prepared by Babco (Richmond, CA), and the rat SCP antibody was made in house. All reagents were purchased from Sigma (St. Louis, MO) except the peptides, which were synthesized by Applied Biosystems (Foster City, CA).
LM immunocytochemistry. A number of methods were used, but the procedure that consistently gave superior results was one adapted from Llewellyn-Smith et al. (1985)
EM immunocytochemistry. The procedure was adapted from Reed et al. (1988)
Release preparation. The ARC-buccal ganglion preparation was isolated as described previously (Cohen et al., 1978
The ARC artery was cannulated with a 30 gauge blunt needle and perfused with ASW at 20 µl/min with a multistaltic pump. The dead volume of the perfusion system was ~100 µl so that solutions perfusing the ARC could be changed while a constant flow rate was maintained. The perfused muscle was hung outside a 60 mm dish, and the nerve connecting the ARC to the ganglion was passed through a slit in the side of the dish, so that the buccal ganglion could be pinned inside the dish. The slit was filled with silicone grease, the ganglion was desheathed, and the ARC was partially encased with parafilm coated with silicone grease. The parafilm formed a subchamber around the ARC, preventing it from drying out, and the silicone grease prevented nonspecific adsorption of released peptides. The dish was clamped onto a platform with the ARC hanging off the side, permitting drops of ARC perfusate to form and fall freely. The drops were collected every 2.5 min into glass test tubes (12 × 75 mm) that were then processed for RIA. The solution bathing the ganglion contained 25% isotonic MgCl2 to prevent spontaneous activity of the neurons in the ganglion. This arrangement ensured that only the motorneuron being fired could be responsible for the peptide released within the ARC. The motorneuron was impaled with two independent glass microelectrodes, one for recording voltage and one for injecting current. The resulting configuration of the release preparation is illustrated in Figure 1. The temperature of the preparation was maintained at 15 ± 0.5°C (i.e., the temperature of the aquaria housing the animals) by cooling the room with an air conditioner. 
Fig. 1. Diagram of the preparation used to measure peptide release within the ARC. The buccal ganglion is bathed in high-Mg2+ ASW to prevent spontaneous neuronal activity. The motorneuron is impaled with two microelectrodes (one to measure voltage, the other to inject current). These conditions enable precise control over the firing of the motorneuron and ensure that only the motorneuron being fired is responsible for the peptide released within the ARC. The ARC (medium gray) is suspended outside the dish and encased in silicone grease (light gray) and parafilm to prevent dehydration. The nerve connecting the buccal ganglion to the ARC runs through a slit in the side of the dish that is subsequently filled with silicone grease to prevent leakage of solutions from the dish. The ARC is perfused via an artery midway along its length, and the perfusate is collected in drops directly into the tubes that are subsequently used for the measurement of their peptide content. The temperature and length of the ARC were also measured with a temperature probe mounted on an isotonic force transducer (not shown). The tip of the temperature probe was inserted at the bottom of the loop between the base muscle (dark gray) and the artery.
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RIA. A 3-(p-hydroxyphenyl)-propionic acid (desamino-tyrosyl) derivative of buccalin A was prepared by reaction of 1 µmol of peptide, 1 µmol of triethylamine, and 3 µmol of Bolton-Hunter reagent [3-(p-hydroxyphenyl)-propionic acid N-hydroxy-succinimide ester] in 100 µl of dimethylformamide for 6 hr at 4°C followed by purification on RP-HPLC with a 15-45% acetonitrile gradient with 0.01 M TFA as counterion.
Peptides (the desaminotyrosinoyl-buccalin or SCPb) were iodinated with 125I using chloramine-T as follows. To the peptide (~1 nmol in 10 µl of 0.5 M phosphate buffer, pH 7.0) was added the radioactive sodium iodide solution (1.5 mCi in 1-3 µl) followed by 5 µl of chloramine-T solution (freshly prepared in the 0.5 M phosphate buffer, 2 mg/ml), and the solution was mixed well by repeated pipetting with an aerosol barrier tip. Sodium metabisulfite (100 µl of 5 mg/ml in the 0.5 M phosphate buffer) was added 15-30 sec after the chloramine-T, and the solution was mixed by repeated pipetting for 1 min. After another 4-5 min, the iodination mixture was applied to a Sep-Pak (C18, Waters Associates, Milford, MA) that had been wetted previously with acetonitrile and rinsed with distilled water. The Sep-Pak was washed with 20 ml of water (discarded as waste), and the peptide was eluted with 80% aqueous acetonitrile containing 0.01 M TFA (a total of 5 ml collected in 1 ml fractions). Usually, the first 1 ml fraction was kept and the others discarded after counting revealed that the majority of the elutable radioactivity resided in the first fraction. The partially purified (by Sep-Pak) trace could be kept for several months in the freezer as a stock for HPLC purification of monoiodinated peptide. Because some uniodinated and unoxidized peptide remained in the Sep-Pak purified trace, it was treated with 1% H2O2 for 1 hr to fully oxidize all methionine residues to the sulfoxides. After this treatment, the desired monoiodo form of the peptide could be separated from both the uniodinated and the diiodinated forms on RP-HPLC with a gradient as above. Radioactive peaks corresponding to the monoiodinated form were lyophilized and resuspended in RIA buffer (154 mM NaCl, 10 mM Na2HPO4, 50 mM EDTA, 0.25 mM merthiolate, 1% BSA, pH 7.5) to a final activity of 10,000-15,000 cpm per 100 µl. Antibodies were diluted in RIA buffer to a point at which 100 µl would bind ~50% of the counts in 100 µl of iodinated peptide trace. The sample volume (blanks, peptide standards, perfusate) was 50 µl in each reaction. The reaction was carried out for 2-3 d at 4°C and was terminated by the addition of 2 ml of RIA charcoal (10 mM Na2HPO4, 0.25 mM merthiolate, 0.25% activated charcoal, 0.025% 70,000 kDa dextran, pH 7.5). After 15 min, the samples were spun to separate the charcoal and supernatant. The supernatant, containing the bound peptide, was decanted and counted in a gamma counter. Standard curves were generated from serial dilutions of peptide in ASW containing 1% BSA to prevent sticking of the peptide to the tubes and pipette tips. The sample volume was 50 µl, which matched the volume of the drops in the experiment, and each tube had half the peptide of the previous tube. A spreadsheet program (Kaleidagraph 2.1) was used to plot the standard curves, to convert counts bound to femtomoles of peptide in the unknowns, and to graph the data. A statistical analysis program (StatView 4.5) was used to perform a within-subjects repeated-measures ANOVA on relevant data to assess the overall level of statistical significance. Individual comparisons were performed using paired t tests. All reagents were obtained from Sigma, except where noted otherwise.
RESULTS
The ARC is innervated by a limited number of neurons
Electrophysiological evidence indicates that B15 and B16 are the only motorneurons that innervate the ARC (Cohen et al., 1978
Fig. 2. Cobalt backfill of a buccal ganglion from the ARC muscle. The arrow points to two neurons in the rostral aspect of the ventral motorneuron cluster stained for cobalt. The size and position of the neurons are consistent with the larger one being B15 and the smaller one being B16. Scale bar, 0.5 mm. This agrees with the electrophysiological data indicating that the ARC is innervated by only two motorneurons.
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Antibody staining corresponds to the biochemical localization
Figure 3, A1 and A2, shows the simultaneous staining of a buccal hemiganglion with a rabbit BUCa antibody and a rat SCPb antibody. The buccal hemiganglion shows cells in the positions, respectively, of B15 (white arrowheads), which stains for both SCP (A1) and buccalin (A2), and B16 (black arrowheads), which stains for buccalin alone. These patterns match the previously reported distribution of staining and biochemical localization in the buccal ganglion for SCP (Lloyd et al., 1987a
Fig. 3. Buccalin and SCP immunostaining in whole mounts of buccal ganglion and ARC muscle. SCP was stained with a primary antibody generated in the rat and a lissamine rhodamine-conjugated, donkey anti-rat secondary antibody. Buccalin was stained using a primary antibody generated in the rabbit and a fluorescein-conjugated, donkey anti-rabbit secondary antibody. A1 shows buccalin immunostaining of the buccal hemiganglion with the commissure on the right, and A2 shows SCP immunostaining of the same field. The black arrowheads point to a neuron staining for buccalin and SCP, which is of a size and position to be B15. No other cells in the buccal ganglion exhibited costaining for buccalin and SCP. White arrowheads point to a neuron staining for buccalin without staining for SCP, which is of a size and position to be B16. B1 shows buccalin immunostaining of the ARC, and B2 shows SCP immunoreactivity of the same field. The black arrowheads point to processes staining for buccalin and SCP, indicating that they belong to B15. White arrowheads point to processes staining for buccalin alone, indicating that they belong to B16. Notice that the B15 and B16 processes are often separated by many micrometers and seem to innervate spatially distinct areas of the ARC. Scale bar (shown in B2), 200 µm.
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Buccalin and SCP are found in the same processes
The distribution of peptide staining in the ARC (Fig. 3B1,B2) is consistent with the known innervation of this muscle. Some processes stain for SCP and buccalin (black arrowheads), indicating that they belong to B15, whereas other processes (white arrowheads) stain only for buccalin, indicating that they belong to B16. There appears to be relatively little overlap between the B15 and B16 innervation of the ARC because the two types of processes are found in distinct locations of the ARC, often separated by tens of micrometers. Because B15 is the only neuron in the buccal ganglion to stain for both SCP and buccalin, and because costaining processes do occur in the ARC, costaining for SCP and buccalin is a convenient way of identifying B15 innervation in the ARC.Buccalin, like SCP, is stored in large dense-core vesicles and not in small clear vesicles
Three lines of evidence enable the unequivocal identification of B15 processes in the ARC. First, B15 and B16 are the only motorneurons known to innervate the ARC (Cohen et al., 1978
Fig. 4. Postembedding immunogold labeling of buccalin and SCP in a B15 neuromuscular junction of the ARC. Cross section of a muscle fiber and B15 terminal in the ARC stained for buccalin (10 nm gold) and SCP (5 nm gold). The presence of buccalin and SCP staining identifies this as a B15 terminal. Note that peptide staining is over the DCVs, not the SCVs, and that many DCVs stain for both buccalin and SCP. The arrow points to an active zone with a number of docked SCVs; note the absence of postsynaptic specializations. f, Myofibrillar bundle in the muscle fiber; g, capping glial process; m, mitochondrion in B15 terminal; c, small clear synaptic vesicles; d, large dense-core vesicles. Scale bar, 0.5 µm.
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SCP and buccalin are stored in the same dense-core vesicles
Figure 5, A1 and B1, also shows numerous DCVs staining for both SCP (large particles) and buccalin (small particles). As in Figure 4, there are many DCVs that stain for buccalin alone. The sizes of the gold particles used to visualize buccalin and SCP are reversed in Figures 4 and 5, yet the distribution of staining is quite similar. This indicates that the more widespread buccalin staining is not an artifact caused by the size of the gold particles. In Figure 5, A1 and A2 show serial sections of the same terminal. In A2, the antibody to buccalin was adsorbed with 50 µM BUCa, and the small particles corresponding to the buccalin staining disappear, leaving only the larger gold particles corresponding to the SCP staining over the DCVs. B1 and B2 also show serial sections of the same terminal. In B2, the antibody to SCP was adsorbed with 50 µM SCPb, and the large gold particles corresponding to the SCP staining disappear, leaving only the small particles corresponding to the buccalin staining over the DCVs. Thus, the costaining of the DCVs for SCP and buccalin is unlikely to be an artifact of cross-reactivity, because adsorption of the primary antibodies with 50 µM of the appropriate peptide resulted in the selective disappearance of the corresponding staining.
Fig. 5. Adsorption controls for immunogold labeling of SCP and buccalin in B15 terminals of the ARC. A1 is a cross section stained for SCP (10 nm gold) and buccalin (5 nm gold) showing that many DCVs costain for both. A2 is a serial cross section of the same process as A1 stained in parallel, except that the buccalin primary antibody was pre-adsorbed with synthetic buccalin showing that only the SCP staining remains (10 nm gold). B1 is a longitudinal section stained for SCP (10 nm gold) and buccalin (5 nm gold), also showing that many DCVs costain for both. B2 is a serial longitudinal section of the same process as B1 stained in parallel, except that the SCP primary antibody was adsorbed with synthetic SCP, showing that only the buccalin staining remains (5 nm gold). Scale bar (shown in B2): 0.5 µm.
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Figure 6 shows the combined results from 117 micrographs (5 different preparations) of stained B15 terminals and processes which, taken together, indicate that SCP and buccalin are costored in all DCVs within B15 terminals. For each of the staining conditions, the data were combined simply by counting morphologically distinguishable DCVs that stained for either peptide alone, both peptides, or neither peptide and expressing that population as a percentage of the total DCVs. This type of analysis was possible because the background staining was low and because both sides of the sections were exposed to antibody. A DCV was considered labeled if it had a gold particle within 15 nm of its perimeter, because the dimensions of an antibody molecule can allow the gold particle to lie this distance away from the peptide's antigenic site (Ottersen, 1989 
Fig. 6. Summary of data obtained from immunogold double labeling of B15 terminals in the ARC. Bars represent the percentage of dense-core vesicles that stained for the peptide indicated below the bar. A dense-core vesicle was considered labeled if a gold particle was within 15 nm of its perimeter. The total number of DCVs used to generate the graph is indicated on the y-axis. A1, Rabbit anti-buccalin and rat anti-SCP staining resulted in double labeling of about half of the DCVs. A2, Rabbit anti-SCP and rat anti-SCP staining also resulted in double labeling of about half of the DCVs, suggesting that differences in antibody potency, not differential localization, account for the staining pattern in A1. Also note that >90% of DCVs stain for SCP. B1, Omission or adsorption (with synthetic SCP) of the primary antibody to SCP results in disappearance of the corresponding label. Note that >90% of dense-core vesicles stain for buccalin. B2, Omission or adsorption (with synthetic buccalin) of the primary antibody to buccalin results in the disappearance of the corresponding label. These results indicate that SCP and buccalin are costored in all of the DCVs of B15.
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As shown in Figure 6A1, labeling with rabbit anti-buccalin and rat anti-SCP resulted in costaining of 44.1% of DCVs, whereas another 45.2% stained for buccalin alone. This staining is likely to be specific because omission of the primary antibodies, or adsorption with 50 µM BUCa (B1) or SCPb (B2), resulted in the absence of the corresponding staining. The DCVs that stained only for buccalin (A1) probably do not represent a distinct class of vesicles, because labeling with the rat anti-SCP and a rabbit anti-SCP (A2) produced a similar pattern of staining. In this case, 42.2% of DCVs stained for both rabbit and rat anti-SCP, whereas another 48.6% stained for rabbit anti-SCP alone. Because the antibodies recognize the same peptide, the pattern of staining must be attributable to the greater potency of the rabbit antibodies, suggesting that SCP and buccalin are costored in all of the DCVs of B15. Complete costorage is also suggested by the 94.3% of DCVs that stain for SCP in A2 and the 93.4% of DCVs that stain for buccalin in B1. Taken together, these results argue that all of the DCVs in B15 terminals of the ARC contain both SCP and buccalin and that selective release of these peptides is unlikely. However, it is important to stress that our immunocytological studies are not able to determine whether different dense-core vesicles contain different ratios of the SCPs and BUCs. Consequently, based on morphological studies alone we cannot exclude the possibility that populations of vesicles with differing ratios of peptides are released under different conditions. This issue, which has enormous functional implications, can only be addressed by directly measuring the relative amounts of peptides that are released under different physiologically relevant conditions. Peptides are released within the ARC after physiologically relevant motorneuron stimulation
In developing a preparation to directly measure peptide release within the ARC, the ability to measure minute quantities of peptide was essential. RIA was the detection system of choice because it is relatively specific and can detect small amounts of peptide. In searching for antibodies that would give the greatest possible sensitivity, we observed that the antisera generated with BSA-conjugated peptides were far superior to those generated with BTG-conjugated peptides and that the antisera generated in rabbits were superior to antisera generated in rats. In fact, all of the antisera that were ultimately used for the RIAs were generated in rabbits against BSA-conjugated peptides.
Figure 7 shows the standard curves of the RIAs that were used to measure peptide release from B15. The RIAs that were eventually used to measure SCP release used the Morris rabbit anti-SCPb at 1:5000 incubated for 2 d, which gave a percent binding (%B) of 55.50 ± 0.9%, a 50% displacement of counts bound (IC50) of 11.04 ± 0.46 fmol, and could detect less than 1 fmol of SCPb. The rabbit anti-BUCa coupled to BSA (rabbit 2, bleed 8) at 1:10,000 for 2 d gave a %B of 65.96 ± 0.75%, an IC50 of 18.38 ± 1.29 fmol, and could detect <1 fmol of BUCa. The buccalin assay was 10-fold less sensitive to BUCb than to BUCa (data not shown). 
Fig. 7. RIA standard curves for SCP and buccalin. The curves were generated with 125I-labeled peptide, peptide antibody, and serial dilutions of peptide standard. Femtomoles of unlabeled peptide are plotted against the percentage of counts bound to antibody. Zero peptide added was taken as 100% bound and typically accounted for approximately half of the total counts. Each data point is the average ± SE of five separate standard curves generated over a 5 month period. The SCP assay used a 1:5000 dilution of antibody that bound 55.50 ± 0.90% of the counts after a 2 d incubation. The SCP assay had an IC50 of 11.04 ± 0.46 fmol. The buccalin assay used a 1:10,000 dilution of antibody that bound 65.96 ± 0.75% of the counts after a 2 d incubation. The buccalin assay had an IC50 of 18.38 ± 1.29 fmol. The RIAs are quite sensitive and are capable of detecting <1 fmol of peptide.
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Increasing the antibody dilution decreased %B and IC50, whereas prolongation of the incubation time generally increased %B and decreased IC50. The assays do not detect peptides from different families, and not all peptides within a family are detected equally well (data not shown). Because the relative binding of all of the members of families is unknown, comparative assays of the absolute amounts of different families is not possible. However, the relative amounts of a single family of peptides (e.g., the buccalins) can be gauged from one sample to the next because these are quantitatively related. Because the RIAs are probably measuring the release of more than one peptide cotransmitter within a family (D. Price, unpublished observations), the release of the family is referenced (i.e., SCP = SCPa,b and BUC = BUCa,b, etc.) in the release experiments. The geometry of the preparation used to measure release from the ARC was equally important for the measurement of peptide release. The quantities of peptides released in the ARC were expected to be low, so the dilution of these peptides was minimized. Furthermore, such small quantities of peptides tend to stick to plastics such as tubing, pipette tips, etc., so the contact of the peptides with such materials was limited. These requirements were satisfied by isolating the ARC in a siliconized subchamber with minimal dead volume, slowly perfusing with ASW, and collecting the perfusate as drops directly into the test tubes that would be used subsequently in the measurement of their peptide content. The kinetics of peptide release within the ARC could also be examined with this arrangement. Finally, the isolation of the buccal ganglion in a dish containing elevated MgCl2 prevented spontaneous activity but permitted individual motorneurons to be impaled with microelectrodes, thus allowing the firing to be regulated.
Because the EM immunocytochemistry indicated that these peptide families are costored in the same DCVs, we expected that these peptides would also be coreleased. In Figure 8, alternate samples (2.5 min each) of ARC perfusate were analyzed for either their SCP or their BUC content. After collecting a baseline for 30 min, motorneuron B15 was fired for 1 hr (black bars), a period that is less than the duration of a normal meal, and in a pattern and frequency that matched the pattern and frequency recorded during normal feeding (Cropper et al., 1990c 
Fig. 8. Corelease of SCP and buccalin within the ARC in response to stimulation of motorneuron B15. During the period indicated by the bar, the neuron was fired at 12 Hz for 3.5 sec every 7 sec, which is within the physiological range of B15 firing. Samples of ARC perfusate were collected every 2.5 min and analyzed by RIA for their peptide content. Alternate samples were analyzed, respectively, for their SCP or buccalin content. A1, SCP and buccalin release in a single experiment. A2, Same as A1, except that buccalin was scaled by multiplying each buccalin measurement by 2.6, the ratio of total SCP measured divided by the total buccalin measured. With this method, the total SCP and buccalin were taken as identical, enabling a more direct comparison of SCP and buccalin profiles. B1, SCP and buccalin release from four experiments was expressed as a percentage of the total amount of peptide (SCP + buccalin) released in the experiment, and the percentages were averaged for each 5 min period. B2, Same as B1, except that buccalin was scaled so that total percentages were equal for both SCP and buccalin, enabling a more direct comparison of their profiles. Peptide content of the samples increases after stimulation of B15, reaches a peak, and then declines even though the neuron is still being stimulated. BUC, Buccalin.
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Figure 8A1 shows the results from a single experiment in which motorneuron B15 was fired at 12 Hz for 3.5 sec every 7 sec during the period indicated by the black bar. The SCP and buccalin content in the perfusate increases after stimulation of B15, reaches a peak, and then declines, even though the motorneuron continues to be stimulated. A further decline is observed after termination of motorneuron stimulation. This pattern of release is not caused by a decrease in the health of the preparation, because the pattern is repeatable in the same preparation and many preparations remain viable for >12 hr. Figure 8B1 illustrates the combined results from four preparations under the same conditions. Because the absolute amounts of the peptides detected varied in different experiments, the release was normalized to the ability of the preparation to release peptides. The SCP and BUC content in each 5 min bin is normalized to the total of all of the buccalin and SCP detected in the experiment. Identical bins in each of the four experiments are then averaged (±SE) and plotted against time (sample number). These data mirror the results from the single experiment, showing that the SCP and BUC content increases, reaches a peak, and then declines as the motorneuron is stimulated with its in vivo firing pattern (Cropper et al., 1990c
The similarity in release profiles for BUC and SCP content seen in Figure 8, A1 and B1, is highlighted when the BUC content is scaled in such a manner that total BUC equals total SCP. In A2, the BUC content in each sample collected during the stimulation of B15 is multiplied by 2.6 to scale it to the SCP content in the same period. In B2, the BUC percent of total for each bin is multiplied by 2.4 to scale it to the SCP percent in the same period. The similarity between SCP and BUC profiles is consistent with their release from the same dense-core vesicles. Peptide release within the ARC changes with time
The results shown in Figure 8 suggest that peptide release from the motorneurons in the ARC is not constant over time, even with constant stimulation. The decline in peptide content in the perfusate after continued motorneuron stimulation is most likely caused by a decrease in peptide release from the motorneurons. However, the increase in peptide release seen at the beginning of peptide stimulation could also be explained by the diffusion of the released peptide into the perfusate. This diffusion is difficult to quantify, so we used another approach to determine whether the peptide release increases in the initial stages of motorneuron stimulation.
Figure 9 shows the results from experiments in which the total duration of B15 stimulation was varied between 5 and 10 min while the other stimulation parameters were kept constant (12 Hz, 3.5 sec on, 3.5 sec off). An ABCA paradigm (i.e., 10, 7.5, 5, and 10 min) was used so that changes in peptide release over the course of the experiment could also be assessed and controlled for. A shows the results from one such experiment in which SCP was measured. Reducing the total duration of stimulation diminished the total amount of SCP measured in the same period. However, the total number of action potentials was not the same in these periods, so the difference could be attributable simply to a difference in the total number of action potentials delivered. That this is not the case is shown in B, in which release is expressed per action potential and is normalized for the ability of the preparation to release peptide by expressing the release at each duration within a single experiment as a percent of the average release for all three durations (5, 7.5, and 10 min). For BUC (n = 5) and SCP (n = 5), the mean ± SE for the normalized release per action potential is then plotted against the total duration of stimulation. The results indicate that there was a significant overall increase in the release of SCP (F(2,8) = 4.46; p < 0.05) and for buccalin (F(2,8) = 12.57; p < 0.005). We observed a slight but significant increase in the amount of peptide released at 10 min compared to 5 min (p < 0.05), suggesting that peptide release does, in fact, increase in the initial phases of motorneuron stimulation. 
Fig. 9. Effect of the total duration of B15 stimulation on peptide release within the ARC. A, Results from a single experiment in which SCP release is measured continuously while periods of stimulation of varying duration are applied; the interburst interval (3.5 sec), the intraburst frequency (12 Hz), and the duration of bursts (3.5 sec) were kept constant. SCP release increases as the period of stimulation lengthens, but the number of action potentials delivered also increases. B, The total released peptide at each of the three durations is corrected to give the release per action potential. This value for each of the three total durations was normalized to the average release for that experiment. The resulting percentage of average release from five separate experiments for each peptide was averaged for each of the three durations. For each peptide, the mean percentage of average release ± SE is plotted against the duration. The results are similar for the two peptides and indicate that there is a slight, but significant, increase in the amount of peptide released per action potential as the duration increases from 5 to 10 min. BUC, Buccalin.
[View Larger Version of this Image (24K GIF file)]
Peptide release is calcium-dependent
Peptide release in a number of systems is calcium-dependent. In many of these systems, the calcium dependence of peptide cotransmitter release has been used as a control to rule out the nonspecific release of cellular contents attributable to the toxicity of the stimulation method (e.g., massive depolarization by means of KCl; Mason et al., 1984
Fig. 10. Effect of extracellular calcium concentration on peptide release from B15 in the ARC. A, Results from a single experiment in which SCP release is measured at different calcium concentrations in the perfusate while the intraburst frequency (12 Hz), the burst duration (3.5 sec), the interburst interval (3.5 sec), and the total duration (10 min) are kept constant. SCP release increases with the calcium concentration. B, The total released peptide at each of the calcium concentrations is normalized to the average release for that experiment. The resulting percentage of average release from five separate experiments for SCP, and six separate experiments for buccalin, was averaged for each of the three calcium concentrations. For each peptide, the mean percentage of average release ± SE is plotted against the calcium concentration. The results are similar for the two peptides, indicating that the release of both peptides from B15 is calcium-dependent. BUC, Buccalin.
[View Larger Version of this Image (24K GIF file)]
Peptide release is independent of muscle contraction
An ARC preparation with pharmacologically blocked contractions is an important control for the possibility that peptide release is an artifact caused by the contraction of the ARC, e.g., that the peptides are simply being squeezed out of some extracellular store by muscle contraction. This possibility was ruled out by blocking muscle contractions with hexamethonium, which blocks the depolarization produced by acetylcholine in this neuromuscular system (Cohen et al., 19784 M hexamethonium chloride was present in the perfusate in the second and fourth stimulation periods to completely block the ARC contraction (data not shown). Blocking ARC contractions with hexamethonium had no effect on the peptide content of the samples, indicating that release was unaffected. The combined data from eight experiments, four measuring each peptide (Fig. 10B), show that blocking the ARC contractions had no effect on SCP or BUC release within the ARC (p > 0.8 for each of the peptides). Thus, the release of peptides from the ARC is not caused by the contraction of the muscle squeezing out peptides trapped in the muscle tissue.
Fig. 11. Effect of hexamethonium on peptide release from B15 in the ARC. A, Results from a single experiment in which buccalin release is measured in the presence or absence of 10
[View Larger Version of this Image (25K GIF file)]
DISCUSSION
If peptide cotransmitters play a role in normal behavior, then their release under physiologically relevant conditions should be demonstrable. In previous studies of vertebrate systems, indirect measurements of peptide release have often been used, e.g., depletion, elevation of second messengers (Uchida et al., 1990The ARC is an advantageous preparation for studying cotransmission
The accessory radula closer and its innervation constitute an advantageous system for studying the behavioral role of peripheral neuromodulation and cotransmission. This muscle is innervated by only two cholinergic motorneurons that contain bioactive neuropeptides. When exogenously applied, these peptides modulate the muscle contractions. The simplicity of this preparation increases the probability of establishing a functional connection between cellular processes of cotransmission and the regulation of behavior. Even in this simple system, however, one cannot even begin to understand the function of cotransmission without understanding the conditions under which neuropeptides are being released. The presence of partially antagonistic transmitter molecules within one neuron makes this undertaking even more challenging. To characterize the release and possible functions of neuropeptides, we used a combination of morphological, electrophysiological, and biochemical techniques. First, we characterized the subcellular localization of the partially antagonistic neuropeptides and then proceeded to characterize the conditions under which these peptides are released.Peptide cotransmitters with partially antagonistic actions are stored within the same DCVs in motorneuron terminals of the ARC
Previous evidence indicated that the SCPs are stored in DCVs and not SCVs within motor terminals in the ARC (Cropper et al., 1987a
The buccalins, like the SCPs, are stored in large dense-core vesicles of motorneuron B15. Although the buccalins and SCPs have partially antagonistic actions, they are stored within the same DCVs. This finding suggests that SCP and buccalin are not released independently from motorneuron B15. However, these results do not exclude the possibility that different subpopulations of DCVs contain different ratios of SCPs and BUCs and are differentially released. This possibility was excluded by the experiments in this and the companion paper (this issue), in which we measured the relative amounts of BUCs and SCPs released under different conditions of stimulation. Peptide cotransmitters are likely to be released during normal behavior
The indirect evidence for SCP release within the ARC includes depletion of SCP, elevation of cAMP, stimulation of PKA activity (Hooper et al., 1994a
When motorneuron B15 is stimulated, buccalin and SCP appear in the perfusate with identical kinetics. This similarity in release profiles is consistent with corelease from the same DCVs. Thus, the ultrastructural immunocytochemistry and similarity in release kinetics both point to costorage of SCP and buccalin in the same DCVs. The release of modulatory peptides changes over time and, therefore, is reminiscent of the post-tetanic potentiation and depression described for primary transmitter release. After stimulation of the motorneuron, the release of peptide increases, reaches a peak, and then declines, even though the motorneuron continues to be stimulated. The depression of peptide cotransmitter release within the ARC could result from depletion of the releasable pool, although results from separate experiments suggest that <20% of the peptide should be depleted from B15 under these conditions (Cropper et al., 1990b
The calcium dependence of peptide cotransmitter release has been reported in other systems (Adams and O'Shea, 1983
The direct demonstration of SCP release supports the hypothesis that the actions of the SCPs released in response to physiologically relevant stimulation of B15 (Cropper et al., 1990b
In summary, the direct measurement of peptide release during the intracellular stimulation of a single motorneuron provides unequivocal evidence of their release. The demonstration that peptides are released when the motorneuron is stimulated with its in vivo firing pattern provides strong evidence that the peptides are released during normal behavior. Furthermore, the released peptides seem to be exerting their modulatory effects on muscle contraction. Taken together, these results support the idea that the modulatory peptides present in the motorneurons act as an intrinsic modulatory system that may play a role in the generation of feeding behavior. In the next paper, the factors that regulate the release of these peptide cotransmitters will be used to test a hypothetical model (Weiss et al., 1992
FOOTNOTES
Received June 24, 1996; revised Sept. 20, 1996; accepted Sept. 24, 1996.
This work was supported in part by National Institutes of Health Grants MH 36730, MH50235, and GM32009.
Correspondence should be addressed to Klaudiusz R. Weiss, Department of Physiology and Biophysics, Mt. Sinai School of Medicine, 1 Gustave L. Levy Place, New York, NY 10029.
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