Neuropeptides regulate the cardiac activity of a prosobranch mollusc,Rapana thomasiana

Summary Involvement of neuropeptides in the regulation of cardiac activity in a prosobranch mollusc, Rapana thomasiana, was studied physiologically as well as immunohistochemically. A catch-relaxing peptide (CARP) showed strong inhibitory effects on the heart with a lower threshold than acetylcholine. The action of CARP was in contrast to that of another neuropeptide, FMRFamide, which has previously been shown to enhance the heart beat. Benzoquinonium blocked the effects of acetylcholine and stimulation of right cardiac nerves 1 and 3b, but not those of CARP, suggesting that the effects of nerve stimulation are mainly due to the release of acetylcholine. Immunohistochemical examinations demonstrated that FMRFamide-like and CARP-like immunoreactive neurons are distributed in the visceral ganglia. Although a neuron appeared to show weak immunoreactivity to both antisera, evidence for the coexistence of peptides in a single neuron was not exhibited. Positive immunoreactivity to FMRFamide and CARP antisera also appeared in right cardiac nerves 1 and 3. In the heart, FMRFamide- and CARP-like immunoreactive fibers were restricted to the atrium and the aortic end of the ventricle, consistent with the morphological observation of innervation. The present results suggest that FMRFamide- and CARP-like peptides are involved in regulating the heart beat.     

The actions of the catch relaxing peptide,carp, on identified Helix central neurons

1. The action of the catch relaxing peptide CARP (H-Ala-Met-Pro-Met-Leu-Arg-Leu-amide, AMPMLRL-amide) has been studied on Helix central neurons.2. CARP, at thresholds of 1 nM or less, excited some cells while inhibiting others. CARP modulated the action of acetylcholine, e.g. at 10–100 nM CARP, the acetylcholine response was greatly reduced.3. The inhibitory action of CARP is mediated through an increase in chloride permeability while CARP excitation was dependent on sodium and calcium.4. The use of blocking agents suggested that CARP and acetylcholine acted on separate receptors.     

Localization of FMRFamide- and ACEP-1-like immunoreactivities in the nervous system and heart of a pulmonate mollusc,Achatina fulica

Immunohistochemical localization of two neuropeptides possibly involved in the regulation of cardiac activity in a pulmonate mollusc, Achatina fulica Férussac, was studied. On the ventral surface of the right cerebral ganglion, more than 50 neurons with diameters of 30–50 m showed immunoreactivity to the antiserum of the neuropeptide FMRFamide. Many were also immunoreactive to an antiserum raised against Achatina cardio-excitatory peptide-1 (ACEP-1). Although FMRFamidelike immunoreactive neurons occurred in all components of the subesophageal ganglia, identifiable ACEP-1-like immunoreactive neurons were located only in the visceral ganglion and the right parietal ganglion. In the heart, FMRFamide- and ACEP-1-like immunoreactive fibers were restricted to the atrium and the aortic end of the ventricle, consistent with morphological observations of cardiac innervation. The present results suggest that FMRFamide-and ACEP-1-like peptides are involved in regulating the heart beat of this snail.     

Action and immunoreactivity of neuropeptides in the buccal neuromuscular system of a prosobranch mollusc,Rapana thomasiana

Summary In a prosobranch mollusc, Rapana thomasiana, the catch-relaxing peptide H-Ala-Met-Pro-Met-Leu-Arg-Leu-NH₂ (CARP) was found to depress the contraction of the radula protractor and retractor elicited by electrical stimulations. The action of CARP was in contrast to that of other neuropeptides, H-Phe-Met-Arg-Phe-NH₂ (FMRFamide) and H-Phe-Leu-Arg-Phe-NH₂ (FLRFamide), which enhanced the contraction of the radula protractor and retractor, respectively. By immunohistochemical examinations, FMRFamide-like immunoreactive neurons were found on the rostral side of the right buccal ganglion and the caudal side of the left ganglion, where some CARP-like immunoreactive neurons were also distributed, indicating a possible coexistence of FMRFamide and CARP. FMRFamide- and CARP-like immunoreactivities were also detected in the neuropile of buccal ganglia, radula nerves arising from the ganglia, and nerve fibers in the radula muscles. The present results suggest that FMRFamide- and CARP-like peptides are involved in the regulation of the contraction of the radula muscles.     

Immunohistochemical Localization of Cardio-Active Neuropeptides in the Heart of a Living Fossil, Nautilus pompilius L. (Cephalopoda, Tetrabranchiata)

Neuropeptides play an important role in modulating the effects of neurotransmitters such as acetylcholine and noradrenaline in the heart and the vascular system of vertebrates and invertebrates. Various neuropeptides, including substance P (SP), vasoactive intestinal polypeptide (VIP) and FMRFamide, have been localized in the brain in cephalopods and the neurosecretory system of the vena cava. Previous studies involving cephalopods have mainly focussed on the modern, coleoid cephalopods, whereas little attention was paid to the living fossil Nautilus. In this study, the distributions of the peptides related to tachykinins (TKs) and the high affinity receptor for the best characterized TK substance P (tachykinin NK-1), VIP, as well as FMRFamide were investigated in the heart of Nautilus pompilius L. by immunohistochemistry. TK-like immunoreactivity (TK-LI) was seen associated to a sub-population of hemocytes, VIP-LI glial cells in larger nerves entering the heart, whereas FMRFamide immunoreactivity was distributed throughout the entire heart, including the semilunar atrioventricular valves. The pattern of FMRFamide immunoreactivity matched that of Bodian silver staining for nervous tissue. The NK-1-LI receptor was located on endothelial cells, which were also positive for endothelial nitric oxide synthase-LI (eNOS). The results indicate that neuropeptides may be involved in the regulation of the Nautilus heart via different mechanisms, (1) by direct interaction with myocardial receptors (FMRFamide), (2) by interacting with the nervus cardiacus (VIP-related peptides) and (3) indirectly by stimulating eNOS in the endothelium throughout the heart (TK-related peptides).     

The actions of FxRFamide related neuropeptides on identified neurones from the snail, Helix aspersa

Intracellular recordings were made from identified neurones in the suboesophageal ganglia of the snail, Helix aspersa. The actions of the eight FxRFamide analogues were investigated on these neurones. These peptides included ones isolated from arthropods and nematodes. All the peptides excited certain neurones while inhibiting others, though their relative potencies varied. Overall on neurones inhibited by these peptides the potency order was: DNFLRFamide > FMRFamide > PDVDHVFLRFamide = KNEFIRFamide > FLRFamide > SDRNFLRFamide = SDPNFLRFamide > KHEYLRFamide. However, if the responses are compared on individual cell types, then the picture becomes more complex. For example, on cell F-2, KNEFIRFamide proved to be potent with an EC-50 value of 0.54 microM. On neurones F-13/16 and E-16, PDVDHVFLRFamide was inhibitory while FMRFamide, FLRFamide, SDRNFLRFamide and SDPNFLRFamide were excitatory. In terms of overall excitatory actions, the data are less complete but an approximate order of potency is: FMRFamide > DNFLRFamide > SDPNFLRFamide > PDVDHVFLRFamide > KNEFIRFamide = KHEYLRFamide = SDRNFLRFamide. However this again varies between specific neurones. These results demonstrate that peptides from insects, crustacea and nematodes are active on Helix neurones and may activate specific receptor subtypes, indicating the possible presence of endogenous analogues of these non-molluscan peptides in the Helix nervous system.     

Partial Characterization of a Novel Cardioinhibitory Peptide from the Brain of the Snail Helix aspersa

1. We report the isolation of a peptide from the brain of the snail Helix aspersa by radioimmunoassay using an antisomatostatin.2. The sequencing of an immunopositive fraction showed the presence of a new tridecapeptide, termed Helix cardioinhibitory peptide (HCIP), with the following primary structure : H-Val-Phe-Gln-Asn-Gln-Phe-Lys-Gly-Ile-Gln-Gly-Arg-Phe-NH₂. It is structurally related to the Achatina cardioexcitatory peptide (ACEP-1) and the terminal-ammo acid sequence of HCIP is identical to that of FMRFamide family peptides.3. The synthetic HCIP was tested on heart and neuronal activities and it was found to have inhibitory actions not only on the ventricle but also on visceral neurons of the central nervous system of Helix. Immunocytochemical investigation indicates its presence in visceral and parietal ganglia, in which cells taking part in the regulation of the heartbeat have been previously identified .     

Effects of synthetic peptides on giant neurones identified in the ganglia of an African giant snail (Achatina fulica Férussac). IV

1. The previous papers (Ku et al., 1986; Kim et al., 1987; Yongsiri et al., 1987) reported the effects of the synthetic peptides, i.e. Met-enkephalin, substance P, neurotensin, oxytocin, Arg-vasopressin, proctolin, FMRFamide, ranatensin C etc., on about 20 identifiable giant neurones of an African giant snail (Achatina fulica Férussac). 2. In the present study, the effects of the same peptides on the following Achatina neurones, other than those of the previous papers, were investigated: v-RPLN, v-LPSN, v-VNAN, v-VLN, r-VMN, l-VMN, v-l-VOrN and d-RCDN. 3. Of the neurones tested here, v-RPLN (ventral-right parietal large neurone) was excited slightly by Met-enkephalin, excited markedly by oxytocin, and inhibited by FMRFamide, at 10(-4) M. 4. Of these effects, those of oxytocin and FMRFamide were undoubtedly the direct effects on the neurone tested, whereas those of Met-enkephalin were probably due to the synaptic activations. 5. Another neurone, v-LPSN (ventral-left parietal large neurone), was affected by oxytocin and ranatensin C at 10(-4) M. The two substances sometimes showed similar simple excitatory effects, in other cases biphasic (excitation followed by inhibition) effects, and in a few cases almost no effect. 6. The rest of the neurones tested were not sensitive at all to any of the peptides examined.     

Modulation of Locomotion and Reproduction by FLP Neuropeptides in the Nematode Caenorhabditis elegans

Neuropeptides function in animals to modulate most, if not all, complex behaviors. In invertebrates, neuropeptides can function as the primary neurotransmitter of a neuron, but more generally they co-localize with a small molecule neurotransmitter, as is commonly seen in vertebrates. Because a single neuron can express multiple neuropeptides and because neuropeptides can bind to multiple G protein-coupled receptors, neuropeptide actions increase the complexity by which the neural connectome can be activated or inhibited. Humans are estimated to have 90 plus neuropeptide genes; by contrast, nematodes, a relatively simple organism, have a slightly larger complement of neuropeptide genes. For instance, the nematode Caenorhabditis elegans has over 100 neuropeptide-encoding genes, of which at least 31 genes encode peptides of the FMRFamide family. To understand the function of this large FMRFamide peptide family, we isolated knockouts of different FMRFamide-encoding genes and generated transgenic animals in which the peptides are overexpressed. We assayed these animals on two basic behaviors: locomotion and reproduction. Modulating levels of different neuropeptides have strong as well as subtle effects on these behaviors. These data suggest that neuropeptides play critical roles in C. elegans to fine tune neural circuits controlling locomotion and reproduction.     

Effects of synthetic biologically active peptides on giant neurones identified in the left buccal ganglion of an African giant snail (Achatina fulica Férussac)

1. The effects of synthetic biologically active peptides, including Met-enkephalin, substance P, oxytocin, Arg-vasopressin, proctolin and FMRFamide, on the following four buccal neurones were examined: d-LBAN (dorsal-left buccal anterior neurone), d-LBMN (dorsal-left buccal medial neurone), d-LBCN (dorsal-left buccal central neurone) and d-LBPN (dorsal-left buccal posterior neurone). These peptides were examined at 10(-4) M. 2. Oxytocin excited d-LBAN and slightly excited d-LBCN, while this inhibited d-LBMN. Arg-vasopressin excited slightly d-LBAN and d-LBCN, but this had some times no effect. FMRFamide inhibited d-LBAN, and slightly inhibited d-LBCN. 3. No direct synaptic connection from the two ventral cerebral giant neurones, v-LCDN and v-RCDN, to the four buccal giant neurones was found, though the two cerebral neurones innervate the cerebro-buccal connectives.     

The actions of rfamide neuroactive peptides on the isolated heart of the giant african snail,Achatina fulica

1. The effects of a range of RFamide peptides were examined on the frequency, amplitude and tone of the isolated heart of Achatina fulica.2. FMRFamide, FLRFamide and SDPNFLRFamide were potent excitants while LPLRFamide, KHEYLRFamide and GSFFRFamide were weak excitants.3. DNFLRFamide and SSLFRFamide were potent inhibitory peptides while LFRFamide, GSLFRFamide and KNEFIRFamide were weak inhibitory peptides.4. MRFamide, LRFamide and RFamide were inactive.5. It is concluded that a tetrapeptide sequence is the minimal requirement for activity on the Achatina heart. With the exceptions of DNFLRFamide and in most preparations GSFFRFamide, LRFamide peptides are excitatory while FRFamide peptides are inhibitory.6. Due to its inhibitory effect and high potency, the sequence DNFLRFamide warrants further investigation.     

Mapping study of Achatina giant neurons sensitive to molluscan peptides

1. Mapping studies of the Achatina identifiable neuron types sensitive to the following 6 molluscan peptides were examined under current-clamp.2. These were Ser-Mytilus inhibitory peptide (Ser-MIP), catch-relaxing peptide (CARP), oxytocin, small cardioactive peptide_b (SCP_b), α-bag cell peptide (α-BCP) and egg-laying hormone (ELH).3. These peptides at 10⁻³ M (3 × 10⁻⁴ M for ELH), with 0.5% Fast Green, were applied locally to the neuron to be tested by pneumatic pressure ejection (2 kg/cm² and 400 msec in duration).4. Ser-MIP showed the inhibitory (hyperpolarizing) effects on the majority of neuron types tested.5. CARP also produced inhibition of the 3 neuron types out of 16 types tested.6. Oxytocin had an excitatory effect on two neuron types.7. SCP_b showed excitatory effects on 4 neuron types: the membrane conductance of 1 neuron type, d-RPeAN, measured under voltage-clamp was reduced by the peptide.8. α-BCP showed no effect.9. ELH produced slight inhibition of the 2 neuron types.     

Neuropeptides modulate the transmitter-induced glycogenolysis and gluconeogenesis in leech segmental ganglia

The effects of four neuropeptides (AKH, FMRFamide, proctolin, VIP) on the alterations in glycogen levels induced by other transmitters were studied in isolated leech segmental ganglia. With the exception of FMRFamide, which produced a small increase (14%) in glycogen, the peptides were by themselves without effect on the glycogen levels. Proctolin abolished the glycogenolytic effects of 5-HT, dopamine and octopamine but not histamine. AKH in combination with ACh produced glycogenolysis although each by themselves were ineffective. AKH modified the effects of other transmitters in different ways i.e. by reduction or reversal of effect. VIP and noradrenaline produced an increase in glycogen (cf. noradrenaline alone which decreased glycogen), but did not modify the effects of the other transmitters. FMRFamide produced a complex variety of modulatory effects on the other transmitters. It is concluded that the glycogen stores in leech ganglia, which are localized principally in the glial cells, may be controlled in complex ways by the different combinations of monoamines, amino acids and neuropeptides.     

A variety of Mytilus inhibitory peptides in the abrm of Mytilus edulis: Isolation and characterization

1. Five species of Mytilus inhibitory peptides, MIP_1–5, were isolated from acetone extracts of the anterior byssus retractor muscle (ABRM) of Mytilus edulis. MIP₁ and MIP₂ were shown to be S²-MIP and A²-MIP, respectively, first isolated from the pedal ganglia of the animal.2. All the five peptides had a common C-terminal structure of -Pro-Xaa-Phe-Val-NH₂, which was shown to be important for their biological activity.3. The five MIPs showed similar inhibitory effects on contractions of the ABRM but did not affect catch tension and its relaxation.4. In addition to the MIPs, catch-relaxing peptide (CARP) was also found in the ABRM.     

Native and heterologous neuropeptides are cardioactive in Drosophila melanogaster

Nine neuropeptides isolated from Drosophila melanogaster and five neuropeptides, previously isolated from the CNS of Limulus with antisera to FMRFamide-related peptides, were tested for their effects on the myogenic heart of Drosophila melanogaster. Of the native peptides, TDVDHVFLRF-NH(2) (Dromyosuppressin), DPKQDFMRFamide, and PDNFMRFamide significantly slowed the heart. Of the Limulus peptides, DEGHKMLYFamide (LP1) increased heart rate significantly, GHSLLHFamide (LP2) and PDHHMMYFamide (LP3) decreased the heart's rate, while DHGNMLYFamide (LP4) and GGRSPSLRLRFamide (LP5) had no effect at the concentrations we employed. Dromyosuppressin, DPKQDFMRFamide, and PDNFMRFamide from Drosophila, and LP2 and LP3 from Limulus, which belong to a novel group of peptides structurally unrelated to FMRFamide, are among only a very few substances from within the general group of neuropeptides and neurohormones known to slow the heart of Drosophila, and as such offer an important tool for investigating the molecular mechanisms underlying the control of the pacemaker.     

RFamide neuropeptide actions on the molluscan heart

FMRFamide and the related tetrapeptide FLRFamide are highly excitatory in molluscan non-cardiac smooth muscle. They are also exceptionally excitatory in the atrium and internally perfused ventricle of Busycon canaliculatum. These two peptides, usually thought of as classic molluscan cardio-acceleratory agents are in fact simply two members of a large and ever growing superfamily, the RFamide family, whose phylogenetic distribution has been so elegantly mapped by Walker. Members of this family, often with extended peptide chains (e.g. penta, hepta and decapeptides), stretch in their known distribution from the cnidaria to the chordates. The effects of some of the members of this superfamily (FMRFamide. FLRFamide, YMRFamide, TNRNFLRFamide, SDPFLRFamide, LMS) were examined. The neuropeptides were found to be very potent at very low concentrations (10(-9) M) in the ventricle of both Buccinium and Busycon. Other neuropeptides (HFMRdFamide, SCPb, NLERFamide and pEGRFamide) were found to be without any effect. The Ca2+ dependency of these neuropeptides was also tested. The peptides appear to induce contraction of the ventricles by release of Ca2+ from internal pools. The neuropeptides appear to stimulate contraction in these cardiac muscles through a completely different pathway to Serotonin (the main excitatory neurotransmitter for the cardiac muscle). When the peptides were applied together with Serotonin an additive effect was observed clearly indicating the release of Ca2+ through different pathways. The nature of the RFamide receptor was also tested. It appears that the RFamide neuropeptides mobilize the 2nd messenger IP3 (Inositol trisphosphate), since the IP3 blocker Neomycin Sulphate inhibited the response of the neuropeptides.     

Neuropeptide FF and FMRFamide potentiate acid-evoked currents from sensory neurons and proton-gated DEG/ENaC channels

Acidosis is associated with inflammation and ischemia and activates cation channels in sensory neurons. Inflammation also induces expression of FMRFamidelike neuropeptides, which modulate pain. We found that neuropeptide FF (Phe-Leu-Phe-Gln-Pro-Gln-Arg-Phe amide) and FMRFamide (Phe-Met-Arg-Phe amide) generated no current on their own but potentiated H+-gated currents from cultured sensory neurons and heterologously expressed ASIC and DRASIC channels. The neuropeptides slowed inactivation and induced sustained currents during acidification. The effects were specific; different channels showed distinct responses to the various peptides. These results suggest that acid-sensing ion channels may integrate multiple extracellular signals to modify sensory perception.     

Histochemical localisation of FMRFamide-gated Na+ channels in Helisoma trivolvis and Helix aspersa neurones

FMRFamide-gated Na⁺ channels of molluscan neurones belong to the ENa/Deg family of channels which have diverse functions. FMRFamide (Phe-Met-Arg-Phe-NH₂) Na⁺ channels were detected electrophysiologically in specified neurones of Helix (Helix aspersa) and Helisoma (Helisoma trivolvis), and clones (FaNaCs) subsequently identified. We have now made a study to determine the distribution of mRNA for the clones HaFaNaC (Helix) and HtFaNaC (Helisoma) in the nervous systems of these species using standard in situ hybridization techniques. Immunohistochemical experiments were also made using an HtFaNaC antibody to detect the channel protein in Helisoma neurones. Many neurones in the central ganglia, including those which exhibit the FMRFamide Na⁺ current, stained for FaNaC-mRNA, suggesting a much wider distribution of the channel than was indicated by the earlier work. An immunoreactive response to the channel antibody was also observed in some Helisoma neurones, such as the giant dopamine neurone of the left pedal ganglion, also shown to possess HtFaNaC-mRNA and to exhibit the FMRFamide Na⁺ current. Taken together, these experiments suggest that the clones HaFaNaC and HtFaNaC are major, if not the only, subunits of the FMRFamide-gated Na⁺ channel detected electrophysiologically in the identified neurones of these species. However, fewer neurones in Helisoma reacted with the HtFaNaC-antibody than those which exhibited message for the channel. This discrepancy may be due to a difference in sensitivity of the two techniques, or because not all of the channel mRNA is normally expressed as a membrane protein.     

The identification, localization, and pharmacology of FMRFamide-related peptides and SCPB in the penis and crop of the terrestrial slug, Limax maximus

1. The molluscan neuropeptides FMRFamide, pQDPFLRFamide, and SCPB were tested on the isolated crop and penis of the terrestraial slug, Limax maximus. FMRFamide and pQDPFLRFamide stimulated the penis and inhibited contractions of the crop. In contrast, SCPB either stimulated or relaxed the penis and increased the tone of the crop. 2. Fibers and varicosities containing immunoreactive (ir-) FMRFamide and ir-SCPB were located in the penis and crop. 3. Extracts of penes, crops, ganglia, and whole animals all contained FMRFamide, FLRFamide, SDPFLRFamide, NDPFLRFamide, and pQDPFLRFamide. 4. These results suggest that the FMRFamide-related peptides and SCPB are involved in the regulation of the reproductive and digestive activities of Limax.