Modulatory mechanisms in the isolated internally perfused ventricle of the whelk Busycon canaliculatum

The action of RFamide neuropeptides on molluscs, with special reference to the gastropods Buccinum undatum and Busycon canaliculatum

The ever-growing RFamide neuropeptide superfamily has members in all animal phyla. Their effects in molluscs, on both smooth and cardiac muscle as well as on neurons, has been studied in detail. These neuropeptides exert a variety of functions: excitatory, inhibitory or even biphasic. Firstly, the literature on the excitatory effect of the RFamide neuropeptides on molluscan muscle and neurons has been reviewed, with greater emphasis and examples from the gastropods Buccinum undatum and Busycon canaliculatum. The peptides seem to be potent activators of contraction, sometimes generating slow tonic force and other times twitch activity. Secondly, the literature on the inhibitory effect of the superfamily has been reviewed. These peptides can exert an inhibitory effect, hyperpolarizing the cells rather than depolarizing them. Thirdly, the neuropeptides may play a variety of other roles, such as contributing to the regulation or maturation process of the animals. There have been cases recorded of RFamide neuropeptides acting as potent venoms in members of the Conus sp. The pathway of action of these multiple roles, their interaction with the parent neurotransmitters acetylcholine and serotonin, as well as the calcium dependency of the RFamide neuropeptides has been discussed, again with special reference to the above mentioned gastropods. A better understanding of the mode of action, the effects, and the importance of the RFamide neuropeptides on molluscan physiology and pharmacology has been attempted by reviewing the existing literature, recognizing the importance of the RFamide neuropeptide actions on molluscs.

RFamide neuropeptide actions on the molluscan ventricle: Interactions with primary neurotransmitters

Different RFamide neuropeptides, some of non-molluscan origin, were examined for their effect on the ventricles of Buccinum undatum and Busycon canaliculatum. None of the peptides tested were inhibitory on these ventricles. All the peptides were extremely active, causing excitation of the preparations at low concentrations. The neuropeptides were then tested with the primary neurotransmitters. In the case of serotonin, the excitatory primary neurotransmitter, the RFamide neuropeptides induced a response, which was greatly enhanced by serotonin. Acetylcholine, the inhibitory neurotransmitter, induced relaxation whenever added, following a neuropeptide. The neuropeptides seemed to be independent of external Ca(2+), since in Ca(2+)-free media tension was induced. On the contrary, serotonin was dependent on external Ca(2+). These findings indicate that the neuropeptides generated tension via a different receptor to that of the primary neurotransmitters, using a different 2nd messenger and activating different Ca(2+) sources. Finally, the parent neuropeptide Phe-Leu-Arg-Phe-NH(2), when added following a different RFamide peptide, excited the preparation further, thus indicating the presence of a receptor that has higher affinity for some structures than others. When Phe-Met-Arg-Phe-NH(2) followed Phe-Leu-Arg-Phe-NH(2), no such response was recorded since the latter is of higher potency than the former.

Length-dependent deactivation of ventricular trabeculae in the bivalve, Spisula solidissima

Shortening-deactivation has been identified and characterized in ventricular trabeculae of the bivalve, Spisula solidissima (Heterodonta, Mactridae). This muscle had ultrastructural similarities to vertebrate smooth muscle. Deactivation was defined as the fraction of maximal force lost during a contraction when a muscle is shortened rapidly (by a quick-release, QR) to a known length, relative to a control isometric contraction at that same length. The magnitude of deactivation was dependent on the size of the release and the point at which the release was applied during the cycle of contraction. QR/quick-stretch (QS) perturbations at the same point during the contraction resulted in negligible deactivation. The magnitude of deactivation was independent of shortening rate. Deactivation was attenuated by applying caffeine (100 microM) and blocked with high extracellular Ca(2+) (56 mM). The Ca(2+) ionophore, A23187 (10 microM), augmented deactivation as did the positive inotrope serotonin (100 nM). Treatment with ryanodine (5 microM) had no significant effect on deactivation. These results suggest that a reduction in Ca(2+) at the contractile element and/or sequestration of Ca(2+) may occur during shortening. Deactivation may minimize the magnitude of work done during active shortening of bivalve cardiac muscle, particularly against the low afterload exhibited in the bivalve peripheral circulatory system. Intracellular Ca(2+) fluxes during sudden length perturbations may explain the effect of stretch on action potential duration in the bivalve heart, as shown previously.

K+ channels in cardiomyocytes of the pulmonate snail helix

We used the patch-clamp technique to identify and characterize the electrophysiological, biophysical, and pharmacological properties of K(+) channels in enzymatically dissociated ventricular cells of the land pulmonate snail Helix. The family of outward K(+) currents started to activate at -30 mV and the activation was faster at more depolarized potentials (time constants: at 0 mV 17.4 +/- 1.2 ms vs. 2.5 +/- 0.1 ms at + 60 mV). The current waveforms were similar to those of the A-type family of voltage-dependent K(+) currents encoded by Kv4.2 in mammals. Inactivation of the current was relatively fast, i.e., 50.2 +/- 1.8% of current was inactivated within 250 ms at + 40 mV. The recovery of K(+) channels from inactivation was relatively slow with a mean time constant of 1.7 +/- 0.2 s. Closer examination of steady-state inactivation kinetics revealed that the voltage dependency of inactivation was U-shaped, exhibiting less inactivation at more depolarized membrane potentials. On the basis of this phenomenon, we suggest that a channel encoded by Kv2.1 similar to that in mammals does exist in land pulmonates of the Helix genus. Outward currents were sensitive to 4-aminopyridine and tetraethylammonium chloride. The last compound was most effective, with an IC(50) of 336 +/- 142 micro mol l(-1). Thus, using distinct pharmacological and biophysical tools we identified different types of voltage-gated K(+) channels.

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.

Comparative potency of some extended peptide chain members of the RFamide neuropeptide family, assessed on the hearts of Busycon canaliculatum and Buccinum undatum

Twenty different RFamide neuropeptide analogues were examined for their relative potencies on the ventricles of Busycon canaliculatum and Buccinum undatum and on the atrium of Busycon to determine the essential requirements for activity at the RFamide receptor. None of the neuropeptide studies was inhibitory to natural cardiac rhythmicity or to FMRFamide (Phe-Met-Arg-Phe-NH(2)) or FLRFamide (Phe-Leu-Arg-Phe-NH(2)) responses. Two tripeptides studied were completely without effect, indicating that a minimum of four amino acids in the peptide chain length was essential for any activity. The original parent tetrapeptide FMRFamide was surprisingly less potent than many of the extended chain peptides such as the penta, hepta and decapeptides. These RFamide neuropeptides were strongly inotropic on both ventricles and the atrium, while on the latter they were strongly chronotropic despite several of these peptides being of a non-molluscan origin. Chain length seems to be of little importance for activity at the receptor. Surprisingly, SCP(B) (small cardioactive Peptide B) was not very effective in either Busycon or Buccinum ventricle. What was also clear was that the configuration of the carboxyl terminal was important for activity. Two neuropeptides in this study possessed an Arg-Met carboxyl terminal and were much less effective than FMRFamide, suggesting that an Arg-Phe terminal is most effective in receptor activation.

5-Hydroxytryptamine stimulates net Ca2+ flux in the ventricular muscle of a mollusc (Busycon canaliculatum) during cardioexcitation

Noninvasive, self-referencing calcium (Ca2+) electrodes were used to study the mechanisms by which 5-hydroxytryptamine (5-HT) affects net Ca2+ flux across the sarcolemma of myocytes from ventricular trabeculae (from a marine gastropod, Busycon canaliculatum). Treatment of isolated trabeculae with 5-HT causes a net Ca2+ efflux, which is 30% blocked by verapamil. These findings suggest that the efflux is in part the result of a previous Ca2+ influx through L-type Ca2+ channels and is due to a rapid Ca2+ extrusion mechanism inherent to the sarcolemma of these myocytes. 5-HT-induced net Ca2+ efflux is also reduced by about 40% by treatment with a sodium (Na+)-free, lithium (Li+)-substituted saline, which shuts down the Na-Ca exchanger during Ca2+ extrusion. Cyclopiazonic acid (CPA), an inhibitor of the sarcoplasmic reticulum (SR) Ca2+ ATPase, almost completely abolishes the 5-HT-induced net Ca2+ efflux, suggesting that the SR rather than the extracellular pool is the primary Ca2+ reservoir serving 5-HT-induced excitation.

Isolation of bioactive compounds from Helix aspersa nerve tissue and the effect of pQPPLPRYamide on heart, esophagus and central neurons of H. aspersa and rectum of Anodonta woodiana

1. Both acetone and methanol extraction was used to isolate bioactive compounds from 1000 Helix aspersa brains. 2. Seven compounds were isolated of which four were identified as follows: Ha-1, 5-hydroxytryptamine; Ha-3, GSPYFVamide; Ha-4, pQPPLPRYamide; Ha-5, SGYLAFPRMamide. There was insufficient material to identify Ha-2, Ha-6 and Ha-7. 3. Ha-4, pQPPLPRYamide, was found to excite the heart of H. aspersa, relax the esophagus and both excite (mainly) and inhibit central neurons. In addition, this peptide contracted the rectum of Anodonta woodiana. 4. It is concluded that pQPPLPRYamide is an example of a new molluscan peptide family, designated as PRYamide.

Modulatory mechanisms in the isolated internally perfused ventricle of the whelk Busycon canaliculatum

1. Isolated cannulated ventricles commenced spontaneous beating on application of perfusion pressure of 10 cm water. Complete hearts showed a fast patterned cyclical rhythm, whereas ventricles devoid of atrial material showed a continuous slow rhythm. 2. Perfused ventricles were inhibited by ACh with a threshold at 10(-8) mol l-1 and arrested at 10(-7) mol l-1, and ventricles under stimulation by 5HT could be arrested by ACh at this concentration. 3. Perfused ventricles were stimulated by 5HT, with threshold at 10(-9) mol l-1 and maximum at 10(-5) mol l-1. Metoclopramide was without affect on 5HT responses, but metitipine and methysergide did inhibit such responses suggesting that the 5HT receptor present possessed mixed properties of the vertebrate 5-HT1 and 5-HT2 receptor subtypes. 4. Ventricles were very sensitive to the excitatory actions of FMRFamide in the 10(-9) to 10(-5) mol l-1 range. Preparations were insensitive to GAPFLRFamide, but SCP-B was modestly excitatory (threshold 10(-7) mol l-1). 5. Preparations were not significantly affected by adenosine, ATP, and guanosine, but GTP was strongly excitatory at 10(-7) mol l-1. 6. 5HT and FMRFamide responses were additive. Preparations responded strongly to the adenylate cyclase activator forskolin and dibutyryl cAMP enhanced spontaneous contractions and 5HT responses, suggesting that the 5HT receptor may operate via a cAMP secondary mechanism. 7. The IP3 inhibitor lithium (10 mmol l-1), caused slight inhibition of FMRFamide responses, suggesting that the receptor to this peptide may operate via IP3 as a second messenger. 8. Neuromodulation in this preparation would appear to involve ACh as inhibitor, 5HT and FMRFamide as upregulators, with no clear roles for FMRFamide-related peptides and GTP.

Ionic dependency of membrane potential and autorhythmicity in the atrium of the whelk Busycon canaliculatum

1. Calcium-free media usually caused a cessation of all electrical and mechanical activity of the Busycon atrium. Where any electrical activity survived, the action potential consisted of a pre- and plateau-like potential devoid of the usual terminal spike. 2. High Ca salines induced tonic force, membrane depolarization and reduction in generation of spontaneous action potentials. The Ca ionophore A23187 enhanced contractions and the SR CaATPase inhibitor cyclopiazonic acid induced slight depolarization, tonic contractures and increased action potential firing. 3. The inorganic Ca antagonist Co2+ was without effect on the preparations, although the lanthanide Gd3+ inhibited contractions and spontaneous action potentials as well as inducing membrane potential depolarization. 4. The organic Ca entry-blocker nifedipine enhanced both spontaneous action potential amplitude and the phasic contractions they generated. 5. High K salines considerably depolarized atrial preparations with accompanying large tonic contractures and suppression of action potentials. The K channel-blocker 4AP enhanced action potential amplitude with slight increase in contractions, and TEA depolarized the atrium, and enhanced action potentials and rhythmic contractions. 6. Sodium-free salines strongly hyperpolarized atrial preparations and abolished spontaneous action potentials and, on washout, the membrane potential became temporarily unstable. In 2 preparations, low chloride and chloride-free media induced significant membrane potential hyperpolarization. 7. It is concluded that, in the atrium, the resting membrane potential is largely determined by the transmembrane K gradient, but with significant conductances to Na and Cl though probably not Ca. The action potential spike appears to be a Ca-dependent event and the plateau-like phase may be a Na-dependent event.

Evolution and overview of classical transmitter molecules and their receptors

All the classical transmitter ligand molecules evolved at least 1000 million years ago. With the possible exception of the Porifera and coelenterates (Cnidaria), they occur in all the remaining phyla. All transmitters have evolved the ability to activate a range of ion channels, resulting in excitation, inhibition and biphasic or multiphasic responses. All transmitters can be synthesised in all three basic types of neurones, i.e. sensory, interneurone and motoneurone. However their relative importance as sensory, interneurone or motor transmitters varies widely between the phyla. It is likely that all neurones contain more than one type of releasable molecule, often a combination of a classical transmitter and a neuroactive peptide. Second messengers, i.e. G proteins and phospholipase C systems, appeared early in evolution and occur in all phyla that have been investigated. Although the evidence is incomplete, it is likely that all the classical transmitter receptor subtypes identified in mammals, also occur throughout the phyla. The invertebrate receptors so far cloned show some interesting homologies both between those from different invertebrate phyla and with mammalian receptors. This indicates that many of the basic receptor subtypes, including benzodiazepine subunits, evolved at an early period, probably at least 800 million years ago. Overall, the evidence stresses the similarity between the major phyla rather than their differences, supporting a common origin from primitive helminth stock.