Peptidergic modulation of male sexual behavior in Lymnaea stagnalis: structural and functional characterization of -FVamide neuropeptides

In the simultaneous hermaphrodite snail Lymnaea stagnalis, copulation as a male is controlled by neurons that send axons to the male copulatory organs via a single penis nerve. Using direct mass spectrometry of a penis nerve sample, we show that one of the molecular ions has a mass corresponding to GAPRFVamide, previously identified from the buccal ganglia, and named Lymnaea inhibitory peptide (LIP). The identity of this peptide is confirmed by partial peptide purification from the penis nerve, followed by post source decay mass spectrometry. We cloned the LIP-encoding cDNA, which predicts a prohormone that gives rise to five copies of LIP (now re-named LIP A), two other -FVamide peptides (LIPs B and C), and five structurally unrelated peptides. The LIP gene is expressed in neurons of the right cerebral ventral lobe that send their axons into the penis nerve. We show that the LIP A peptide is present in these neurons and in the penis nerve, and confirmed the presence of LIP B and C in the penis nerve by post source decay mass spectrometry. Finally, we demonstrate that LIP A, B and C inhibit the contractions of the penis retractor muscle, thereby implicating their role in male copulation behavior.     

Structural and functional characterization of neuropeptides involved in the control of male mating behavior of Lymnaea stagnalis.

Mating as a male in the simultaneous hermaphrodite freshwater snail, Lymnaea stagnalis, comprises a series of complex behaviors that are a prelude to copulation. Copulatory behavior itself is assumed to be controlled by various types of peptidergic neurons as well as serotonergic cells. Here we report the primary structure of two peptides that were extracted from a cluster of neurons that innervates the penial complex and that is located in the anterior lobe of the right cerebral ganglion. The sequences of the peptides were determined as: Ala-Pro-Gly-Trp-amide and Ser-Gly-Ser-Asp-Tyr-Cys-Glu-Thr-Leu-Lys-Glu-Val-Ala-Asp-Glu-Tyr-Ile-Leu- Leu- Ser-Tyr-Lys-Ile-Glu-Glu-Gln-Arg-Ala-Ala-Asp-Cys-Gly-Gly-Glu-Pro-Pro-Asn- Ser- Gln(amide), respectively. The longer peptide is a homodimer. Both peptides are processed from the recently identified Ala-Pro-Gly-Trp-amide prohormone, which is expressed in the neurons of the anterior lobe of the right cerebral ganglion. Ala-Pro-Gly-Trp-amide could also be recovered from the penial complex. This peptide, when applied in vitro, inhibits the contractions of the penis retractor muscles evoked by serotonin in a dose-dependent fashion.     

Peptidomics analysis of neuropeptides involved in copulatory behavior of the mollusk Lymnaea stagnalis

Male copulation behavior in mollusks is controlled by an array of peptide messengers. In the present study, we have used a peptidomics approach employing liquid chromatography in conjunction with electrospray mass spectrometry to characterize peptides contained in the penial complex of the freshwater snail, Lymnaea stagnalis. In addition to the previously described peptides, we have identified a group of novel peptides that share the carboxyl termini of -FVRIamide. A cDNA cloning study revealed the organization of the precursor, which contains 20 peptide domains with the carboxyl termini of -F(X)RIamide which are flanked by many putative proteolytic sites including the KR and the less commonly occurring (G)K and (G)R sites. In addition, there are several monobasic R and dibasic RR and KK sites that may be used for processing. We then used MALDI-TOF/TOF-MS in a data-dependent mode, which selected all the molecular ion species with the predicted masses of the mature -F(X)RIamide peptides, and performed MS/MS analysis on these peptides. This approach allowed us to identify all the predicted -F(X)RIamide peptides. Immunocytochemistry showed the localization of -FVRIamide immunoreactive neurons in several central ganglia, and immunoreactive axons in the penial complex. Finally, application of synthetic -FVRIamide peptides to an in vitro posterior vas deferens preparation showed inhibitory effect on the spontaneous contraction/relaxation cycle of the vas deferens.     

A molluscan peptide alpha-amidating enzyme precursor that generates five distinct enzymes.

Mechanisms underlying the specificity and efficiency of enzymes, which modify peptide messengers, especially with the variable requirements of synthesis in the neuronal secretory pathway, are poorly understood. Here, we examine the process of peptide alpha-amidation in individually identifiable Lymnaea neurons that synthesize multiple proproteins, yielding complex mixtures of structurally diverse peptide substrates. The alpha-amidation of these peptide substrates is efficiently controlled by a multifunctional Lymnaea peptidyl glycine alpha-amidating monooxygenase (LPAM), which contains four different copies of the rate-limiting Lymnaea peptidyl glycine alpha-hydroxylating monooxygenase (LPHM) and a single Lymnaea peptidyl alpha-hydroxyglycine alpha-amidating lyase. Endogenously, this zymogen is converted to yield a mixture of monofunctional isoenzymes. In vitro, each LPHM displays a unique combination of substrate affinity and reaction velocity, depending on the penultimate residue of the substrate. This suggests that the different isoenzymes are generated in order to efficiently amidate the many peptide substrates that are present in molluscan neurons. The cellular expression of the LPAM gene is restricted to neurons that synthesize amidated peptides, which underscores the critical importance of regulation of peptide alpha-amidation.     

Rapid Communication: Neuropeptide Expression and Processing as Revealed by Direct Matrix-Assisted Laser Desorption Ionization Mass Spectrometry of Single Neurons

Abstract: Neuropeptides were directly detected in single identified neurons and the neurohemal area of peptidergic (neuroendocrine) systems in the Lymnaea brain by using matrix-assisted laser desorption ionization mass spectrometry (MALDI-MS). The samples were placed in matrix solution and ruptured to allow mixing of cell contents with the matrix solution. After formation of matrix crystals, the analytes were analyzed by MALDI-MS. It was surprising that clean mass spectra were produced, displaying extreme sensitivity of detection. In one of the neuroendocrine systems studied, we could demonstrate for the first time, by comparing the peptide patterns of soma and of neurohemal axon terminals, that processing of the complex prohormone expressed in this system occurs entirely in the soma. In the other system studied, novel peptides could be detected in addition to peptides previously identified by conventional molecular biological and peptide chemical methods. Thus, complex peptide processing and expression patterns could be predicted that were not detected in earlier studies using conventional methods. As the first MALDI- MS study of direct peptide fingerprinting in the single neuron these experients demonstrate that MALDI-MS forms a new and valuable approach to the study of the synthesis and expression of bioactive peptides, with potential application to single-cell studies in vertebrates, including humans.     

Distribution of tachykinin-related neuropeptide in the developing central nervous system of the moth Spodoptera litura

Neuropeptides with similarities to vertebrate tachykinins, designated tachykinin-related peptides (TRPs), have been identified in several insect species. In this investigation we have utilized an antiserum raised to one of the locust TRPs, locustatachykinin-I (LomTK-I), to determine the distribution pattern of LomTK-like immunoreactive (LTKLI) neurons in the developing nervous system of the moth Spodoptera litura. A number of LTKLI neurons could be followed from the larval to the adult nervous system: a set of median neurosecretory cells (MNCs) in the brain, a pair of brain descending neurons and a few sets on neurons in the ventral nerve cord. The distribution of LTKLI neurons in the adult brain is very similar to that seen in other insect species with prominent arborizations in the central body, antennal lobes, mushroom body calyces, optic lobe neuropils and other distinct neuropil areas in the protocerebrum and tritocerebrum. A new finding is the presence of LTKLI neurosecretory cells with axon terminals in the anterior aorta and corpora cardiaca, suggesting for the first time a neurohormonal role of tachykinin-related peptide(s) in insects. During postembryonic development the number of LTKLI neurons in the ventral nerve cord decreases somewhat, whereas the number increases in the brain. Thus the functional roles of TRPs may change to some extent during development.     

Vasoactive intestinal peptide causes peristaltic contractions in the esophageal body

Vasoactive intestinal peptide (VIP) caused a dose-dependent fall in lower esophageal sphincter (LES) pressure and dose-dependent contractions in the body of the esophagus. The response to VIP in the esophagus or LES was not modified by atropine, phentolamine, haloperidol, pyrilamine, methysergide, indomethacin and tetrodotoxin, showing that it exerts direct action at the esophageal smooth muscle. These studies suggest that VIP causes contraction in the esophageal body and relaxation of the LES by a direct action on the smooth muscle. It is possible that VIP may be the common mediator of noncholinergic, nonadrenergic neurons that cause relaxation of the lower esophageal sphincter and contraction in the esophageal body.     

Peptidergic control of the heart of the stick insect, Baculum extradentatum

The dorsal vessel of the Vietnamese stick insect, Baculum extradentatum, consists of a tubular heart and an aorta that extends anteriorly into the head. Alary muscles, associated with the heart, are anchored to the body wall with attachments to the dorsal diaphragm. Alary muscle contraction draws haemolymph into the heart through incurrent ostia. Excurrent ostia lie on the dorsal vessel in the last thoracic and in each of the first two abdominal segments. Muscle fibers are associated with these excurrent ostia. Crustacean cardioactive peptide (CCAP)- and proctolin-like immunoreactivity is present in axons of the segmental nerves that project to the dorsal vessel, and in processes extending over the heart and alary muscles. Proctolin-like immunoreactive processes are also localized to the valves of the incurrent ostia and to the excurrent ostia. Neither the link nerve neurons, nor the lateral cardiac neurons, stain positively for these peptides. Physiological assays reveal dose-dependent increases in heart beat frequency in response to CCAP and proctolin. Isolating the dorsal vessel from the ventral nerve cord led to a change in the pattern of heart contractions, from a tonic, stable heart beat, to one which was phasic. The tonic nature was restored by the application of CCAP.     

Natriuretic peptides cause relaxation of human and guinea-pig gallbladder muscle through interaction with natriuretic peptide receptor-B

Atrial natriuretic peptide (ANP) binding sites have been demonstrated in the guinea-pig gallbladder muscle with unclear function. To investigate effects of natriuretic peptides in the gallbladder, we measured relaxation of isolated human and guinea-pig gallbladder strips caused by natriuretic peptides, including C-type natriuretic peptide (CNP), brain natriuretic peptide (BNP) and ANP, as well as des[Gln18, Ser19, Gly20, Leu21, Gly22]ANP(4-23) amide (cANP(4-23)), a selective natriuretic peptide receptor-C (NPR-C) agonist. Results in the human gallbladder were similar to those in the guinea-pig gallbladder. CNP, BNP, ANP and cANP(4-23) alone did not cause contraction or relaxation in resting gallbladder strips. However, in carbachol or endothelin-1-contracted strips, CNP caused moderate, sustained and concentration-dependent relaxation. The relaxation was not affected by tetrodotoxin or atropine in endothelin-1-contracted gallbladder strips and not by tetrodotoxin in carbachol-contracted strips. These indicate a direct effect of CNP on the gallbladder muscle. The relative potencies for natriuretic peptides to cause relaxation were CNP>BNP> or = ANP. cANP(4-23) did not cause relaxation. These indicate the existence of the natriuretic peptide receptor-B (NPR-B) mediating the relaxation. Taken together, these results demonstrate that natriuretic peptides cause relaxation of human and guinea-pig gallbladder muscle through interaction with the natriuretic peptide receptor-B.     

Physiologic changes of compound muscle action potentials related to voluntary contraction and muscle length in carpal tunnel syndrome.

The affect of muscle length and voluntary contraction upon compound muscle action potentials (CMAPs) in subjects with carpal tunnel syndrome (CTS) has been evaluated. Twenty-five hands in a CTS patient group and 29 hands in a normal subject control group were studied. The CMAPs from the abductor pollicis brevis induced by median nerve stimulation at the wrist were obtained for five thumb positions: neutral, abduction for shortening with and without contraction, and adduction for lengthening with and without contraction. Upon muscle shortening with relaxation, CMAP duration decreased in both groups, whereas waveform amplitude increased in the control group and showed no significant change in the CTS group. Muscle shortening with contraction afforded decreased CMAP duration and increased CMAP amplitude in both groups. Upon muscle lengthening with relaxation, both groups showed a reduction in CMAP amplitude and an increase in CMAP duration. Upon lengthening with contraction, CMAP duration decreased in the control group; in contrast, the CTS group showed further amplitude reduction and the waveform duration returned to the neutral value. These results demonstrate that, in patients with CTS, physiologic CMAP summations by muscle shortening or contraction may be less effective, whereas decreases in amplitude and increases in duration may be accentuated by lengthening and contraction.     

THE INNERVATION AND PHYSIOLOGY OF THE EXTRINSIC BUCCAL RETRACTOR MUSCLES OF PHILINE APERTA (LINNAEUS)

Two buccal mass retractor muscles of Philine are innervatedby at least 4 excitatory motoneurons, whose cell bodies liein the buccal and the cerebral ganglia. The muscle fibres respondto action potentials generated in the motoneurons or their axonswith excitatory junction potentials (ejps), each of which isfollowed by a small twitch-like contraction. Both the electricaland mechanical responses facilitate and summate with repetitivestimulation. A large ventrally located cerebral neuron (VGC) inhibits tensiondevelopment in the muscle by reducing the amplitude of the excitatoryjunction potentials from and identified buccal motoneuron. Acetylcholinereversibly depolarises and causes tonic contraction of the muscles.This action is partially antagonised by hexamethonium, whichalso blocks the ejps from two axons in the buccal and one inthe pedal nerve 9. 5-Hydroxytryptamine potentiates the ejp fromthe identified buccal motoneuron and enhances the rate of relaxation.Histamine reduces the amplitude of the presumed cholinergicbuccal nerve ejps, but does not affect the hexamethonium sensitiveejp in the pedal nerve 9. In this respect its action resemblesthat of the ventral giant cell.     

Peptidergic innervation of leg muscles of the cockroach,Periplaneta americana (L.), and a possible role in modulation of muscle contraction

FMRFamide-related peptides of insects are particularly important because of their possible function as neurohormones and neuromodulators on a wide variety of tissues. Part of this study was an investigation of the immunofluorescent staining of motor nerves which arise in the metathoracic ganglion, examined in wholemount using an antiserum that recognizes extended -RFamide peptides (generally recognized to be of the FMRFamide family). This antiserum revealed immunochemical staining of numerous cell bodies in the metathoracic ganglion and of axons in peripheral nerve 5, a large nerve which contains both motor and sensory fibres. Axons staining positive for FMRFamide-related peptides were traced in nerve 5 as far as the femur-tibia joint, and into the first (sensory-motor) and third (motor only) ramus of nerve 5. Reverse-phase HPLC with radioimmunoassay revealed a peak of FMRFamide-related peptide activity in nerve 5 that was coincident with a peak found when thoracic ganglia were processed in the same fashion. A physiological assay was devised to test the ability of various non-native peptides to alter the characteristics of contraction of skeletal muscles of the legs. Using neurally evoked contractions of coxal depressor muscles of the metathoracic leg it was determined that several non-native peptides could potentiate muscle contractions.The results of this study suggest that muscles of the legs receive innervation by identifiable, FMRFamide-related peptide-containing neurons and that the release of peptide(s) at the muscle may be yet another method of modulating the mechanics of muscle contraction.Abbreviations D _f fast depressor motor neuron - D _s slow depressor motor neuron - DU M dorsal unpaired median - FaRPs FMRFamide related peptides - FEFe fast extensor of the femur - FFFe fast flexor of the femur - FITC fluorescein isothiocyanate - FPC fast promotor of the coxa - FPT fast flexor of the pretarsus - I _1–3 inhibitory motor neurons - LMS leucomyosuppressin, N5 nerve 5 - N5r1 first ramus of nerve 5 - PBS phosphate buffered saline - PLCl posterior lateral cluster - RIA radioimmunoassay - SETi slow extensor of the tibia - SFTi slow flexor of the tibia - TFA trifluoroacetic acid - VMCl ventral median cluster     

LFRFamides: a novel family of parasitation-induced -RFamide neuropeptides that inhibit the activity of neuroendocrine cells in Lymnaea stagnalis

We report the characterization of a cDNA encoding a novel -RFamide neuropeptide precursor that is up-regulated during parasitation in the snail Lymnaea stagnalis. Processing of this precursor yields five structurally related neuropeptides, all but one ending with the C-terminal sequence -LFRFamide, as was confirmed by direct mass spectrometry of brain tissue. The LFRFamide gene is expressed in a small cluster of neurons in each buccal ganglion, three small clusters in each cerebral ganglion, and one cluster in each lateral lobe of the cerebral ganglia. Application of two of the LFRFamide peptides to neuroendocrine cells that control either growth and metabolism or reproduction induced similar hyperpolarizing K+-currents, and inhibited electrical activity. We conclude that up-regulation of inhibitory LFRFamide neuropeptides during parasitation probably reflects an evolutionary adaptation that allows endoparasites to suppress host metabolism and reproduction in order to fully exploit host energy recourses.     

Involvement of pedal peptide in locomotion in Aplysia: modulation of foot muscle contractions

Pedal peptide (Pep) is a 15-amino-acid neuropeptide that is localized within the Aplysia central nervous system (CNS) predominantly to a broad band of neurons in each pedal ganglion. Pep-neurons were identified by intracellular staining and immunocytology or by radioimmunoassay (RIA) of extracts from identified neurons. RIA reveals that 97% of all Pep-like immunoreactivity (IR-Pep) in pedal nerves is found in the three nerves that innervate the foot. Nearly every Pep-neuron sends an axon out at least one of these three nerves. Application of Pep to foot muscle causes an increase in the amplitude and relaxation rate of contractions driven by nerve stimulation or intracellular stimulation of pedal motor neurons. The increase in relaxation rate was the predominant effect. Intracellular recording in "split-foot" preparations reveals that Pep-neurons increase their overall firing rates and fire in bursts with each step during locomotion. Recovery of IR-Pep from foot perfusate following pedal nerve stimulation increases in a frequency-dependent fashion. Thus it appears that one function of Pep-neurons is to modulate foot muscle contractility during locomotion in Aplysia.     

Extracellular recordings from the motor nervous system of the nematode,Ascaris suum

1. The close association of muscle and neurons in Ascaris suum makes it difficult to determine whether spikes recorded from nerve cords originate in muscle or neurons. We have developed criteria that distinguish muscle and neuronal activity. There are two categories of extracellular spikes. 2. The first category consists of spikes with a wide range of amplitudes, marked by large spikes. These spikes, which can be recorded over lateral muscle and over the dorsal and ventral nerve cords, are abolished when muscle is disrupted or removed, or when curare is applied. Large spikes are relatively infrequent, are correlated with intracellularly recorded muscle events, and respond to polarizations of motor neurons, implying that they originate in muscle. 3. The second spike category, small amplitude spikes, is exclusive to the ventral nerve cord, occurs more frequently than large spikes and displays patterned firing. Small spikes are not affected by muscle removal or by curare, and are correlated with motor neuronal post-synaptic potentials, but not with intracellularly recorded muscle events. We infer that they originate in neurons. 4. Low level activity recorded extracellularly over nerve cords may represent muscle activity due to tonic motor neuronal synaptic transmission. It responds to motor neuronal polarization and is suppressed by curare or muscle removal.     

Fulicin, a novel neuropeptide containing a D-amino acid residue isolated from the ganglia of Achatina fulica

A novel pentapeptide containing a D-amino acid residue was purified from the central ganglia of the African giant snail Achatina fulica Ferussac, and it was named fulicin. The primary structure of the peptide was determined to be Phe-D-Asn-Glu-Phe-Val-NH2. Fulicin potentiated tetanic contraction of the penis retractor muscle of this snail at very low concentrations, and also showed modulatory actions on the activity of the buccal and ventricular muscles and the central ganglionic neurons.     

Copulation in the hermaphroditic snail Lymnaea stagnalis: a review

Summary

Male copulatory behavior of the hermaphroditic snail Lymnaea stagnalis is a complex one: the appetitive behavior consists of a number of elements which do not always appear in the same sequence and have variable durations. Backfills of the penis nerve revealed the neurons that send projections to the male copulatory apparatus. Immunocytochemical experiments have demonstrated that these neurons contain at least ten different messenger molecules. Based on in situ hybridization and chemical purification data, it is suspected that this number will probably be doubled. How the different neurons and the molecules they contain might be involved in generation of the different elements of male copulatory behavior is discussed.     

Neuroanatomical and immunocytochemical studies of the head retractor muscle innervation in the pond snail, Lymnaea stagnalis L

Axonal tracing and immunocytochemical techniques were used to study the innervation of the head retractor muscle (HRM) in the pond snail Lymnaea stagnalis L. Fibers of both the superior and inferior cervical nerves which innervate the HRM form endings that comply with the structure of chemical synapses. The somata of neurons with axons in these nerves are located in all except the buccal ganglia of the central nervous system, and this seems to be a special feature of the HRM motor system. By staining the filamentous actin with Oregon-green conjugated phalloidin, we demonstrated that the HRM has a multiterminal innervation and one muscle fiber can contain several synaptic endings which appear to be both morphologically and physiologically different. The morphological diversity of synaptic vesicles suggests a multiplicity of neurotransmitters acting on these nerve-muscle junctions. Immunocytochemical evidence was found for a strong serotonergic and FMRFamidergic innervation of muscle fibers through axons of the inferior cervical nerve. The thin fibers of the inferior cervical nerve possess immunoreactivity to glutamate, gamma-aminobutyric acid (GABA) and choline-acetyltransferase, and form sparser innervation patterns in the muscle. Our results indicate that several neurotransmitters are present in the nerves innervating the Lymnaea HRM and may therefore participate in the control of this muscle. The possible behavioral significance of such different neurotransmitter sets involved in the regulation of contractions is discussed.     

Mass spectrometric analysis of FMRFamide-like immunoreactive neurons in the prothoracic and subesophageal ganglion of Periplaneta americana

MALDI-TOF mass spectrometry combined with immunocytochemistry and retrograde labeling, was used to study the expression pattern and morphology of Pea-FMRFamide-related peptides in single neurons of the prothoracic ganglion and the subesophageal ganglion (SEG) of the American cockroach Periplaneta americana. In contrast to the postero-lateral cells (PLCs) of the meta- and mesothoracic ganglion, the prothoracic FMRFamide-related peptides expressing neurons not only extend in the posterior median nerve but also in an anterior median nerve, which is described herein. The peptidome of the prothoracic PLCs is identical with that of the meso- and metathoracic neurons, respectively. In this study, we identified a truncated form of Pea-FMRFa-24 which was found to be more abundant than the peptide originally designated as Pea-FMRF-24. FMRFamide-related peptides expressing postero-lateral cells were also detected in the labial neuromere of the SEG. Although their projection could not be solved, mass spectrometric analyses revealed the same peptide complement in these neurons as found in the thoracic postero-lateral cells. In all neurons which we studied no co-localized peptides of other peptide families were observed.     

The modulation of skeletal muscle contraction by FMRFamide-related peptides of the locust

The external ventral protractor muscle of the VIIth abdominal segment, M234, is a skeletal muscle that possesses receptors that recognize a range of FMRFamide-related peptides and application of these peptides results in an increase in the amplitude of neurally evoked contractions with little or no effect on basal tonus. FLRFamide itself has the same biologic activity as the extended peptides, whereas truncation to LRFamide or RFamide results in a peptide with no biologic activity. The receptors recognizing these extended FLRFamides, which include SchistoFLRFamide, seem to be different from the SchistoFLRFamide receptors found on locust oviduct visceral muscle. SchistoFLRFamide and the non-peptide mimetic, benzethonium chloride (Bztc), increase the frequency and amplitude of miniature endplate potentials, increase the amplitude of neurally evoked excitatory junction potentials, and result in a hyperpolarisation of resting membrane potential. Bztc, however, also abolishes the active membrane response that may explain its ability to decrease neurally evoked contractions.