A neurosecretory system terminating in the Helix heart

Nerve-granular cell communication in the atrium of the snail Achatina achatina occurs via the cardioexcitatory transmitters serotonin and FMRFamide

In the present study, the anatomical association and functional interaction between nerve fibres and granular cells in the atrium of the snail Achatina achatina are investigated using a combination of scanning electron microscopy (SEM), pharmacological and immunofluorescence techniques. The SEM studies support a close anatomical association of axons with granular cells and new features of surface morphology are revealed. Pharmacological experiments showed that both serotonin and FMRFamide were able to induce degranulation of granular cells and the release of cysteine-rich atrial secretory protein. Serotonin- and FMRFamide-immunoreactive nerve fibres were observed at variable distances from granular cells, ranging from close contact to distances as far as the diameter of a muscle bundle. These results suggest that serotonin and FMRFamide play a role as paracrine excitatory transmitters in nerve-to-granular cell communication.

Cysteine-Rich Atrial Secretory Protein from the Snail Achatina achatina: Purification and Structural Characterization

Despite extensive studies of cardiac bioactive peptides and their functions in molluscs, soluble proteins expressed in the heart and secreted into the circulation have not yet been reported. In this study, we describe an 18.1-kDa, cysteine-rich atrial secretory protein (CRASP) isolated from the terrestrial snail Achatina achatina that has no detectable sequence similarity to any known protein or nucleotide sequence. CRASP is an acidic, 158-residue, N-glycosylated protein composed of eight alpha-helical segments stabilized with five disulphide bonds. A combination of fold recognition algorithms and ab initio folding predicted that CRASP adopts an all-alpha, right-handed superhelical fold. CRASP is most strongly expressed in the atrium in secretory atrial granular cells, and substantial amounts of CRASP are released from the heart upon nerve stimulation. CRASP is detected in the haemolymph of intact animals at nanomolar concentrations. CRASP is the first secretory protein expressed in molluscan atrium to be reported. We propose that CRASP is an example of a taxonomically restricted gene that might be responsible for adaptations specific for terrestrial pulmonates.

Atrial granular cells of the snailAchatina fulicarelease proteins into hemolymph after stimulation of the heart nerve

The atrium of the gastropod mollusc Achatina fulica receives rich innervation and contains numerous granular cells (GCs). We studied the atrial innervation and discovered that axon profiles typical in appearance of peptidergic neurons form close unspecialized membrane contacts with GCs. Then,we investigated, at both morphological and biochemical levels, the effect of electrical stimulation of the heart nerve on GCs of Achatina heart perfused in situ. The ultrastructural study demonstrated changes in granule morphology consistent with secretion. These events included alteration of granule content, intracellular granule fusion and formation of complex degranulation channels, within which the granule matrix solubilized. It was shown that electrical stimulation resulted in a significant increase of the total protein concentration in the perfusate. Furthermore, SDS-PAGE analysis of the perfusate revealed three new proteins with molecular masses of 16, 22,and 57 kDa. Affinity-purified polyclonal antibodies against the 16 kDa protein were obtained; the whole-mount immunofluorescence technique revealed the presence of this protein in the granules of atrial GCs. In GCs of the stimulated atrium, a progressive loss of their granular content was observed. The results suggest that the central nervous system can modulate the secretory activity of the atrial GCs through non-synaptic pathways.

Ultrastructure of neuromuscular contacts in the embryonic pond snail Lymnaea stagnalis L

Ultrastructural characteristics of muscle fibers and neuromuscular contacts were investigated during two stages of embryogenesis of the pulmonate snail Lymnaea stagnalis. The first muscle cells appear as early as during metamorphosis (50-55% of embryonic development), whereas previously, in the trochophore/veliger stages (25-45%), muscular elements cannot be detected at all. The first muscle fibers contain large amounts of free numbers, a well-developed rER system and only a few irregularly arranged contractile elements. The nucleus is densely packed with heterochromatine material. At 75% adult-like postmetamorphic stage, the frequency of muscle fibers increases significantly, but, bundles of muscle fibers cannot yet be observed. Furthermore the muscle cells are characterized by large numbers of free ribosomes and numerous rER elements. Fine axon bundles and single axon processes, both accompanied by glial elements, can already be found at this time. Axon varicosities with different vesicle and/or granule contents form membrane contacts with muscle fibers, but without revealing membrane specialization on the pre- or postsynaptic side. The late development of the muscle system and neuromuscular contacts during Lymnaea embryogenesis correlates well with the maturation of different forms of behavior of adult, free-living life, and also with the peripheral appearance of chemically identified components of the embryonic nervous system of central origin.

Ultrastructural aspects of peptidergic modulation in the peripheral nervous system of Helix pomatia

The ultrastructural characteristics of peptidergic peripheral contacts in the snail, Helix pomatia, were investigated, with special attention to the innervation of the heart, buccal mass, and salivary gland by Mytilus inhibitory peptide-immunoreactive neurons. Following the application of correlative light- and electron-microscopic pre-embedding immunocytochemistry, the peripheral tissues reveal a rich innervation by Mytilus inhibitory peptide-immunoreactive elements. These neurons establish three types of neuromuscular contacts in the heart and buccal mass: (1) close (16-20 nm) unspecialized membrane contacts; (2) contacts with a relative wide (40-100 nm) intersynaptic cleft; and (3) labeled varicosties located freely in the extracellular space, far (0. 5-several microm) from the muscle cells. In the salivary gland, the immunoractive profiles contact both the muscular and glandular elements with close (type 1) and wider (type 2) membrane attachments. The great majority of Mytilus inhibitory peptide-immunoreactive profiles contain an ultrastructurally uniform population of large (120-150 nm) electron dense granules. The ultrastructural features of the innervation by Mytilus inhibitory peptide-immunoreactive elements are compared with those established by immunogold labelled FMRFamide-containing profiles in the heart and salivary gland. These latter display similarities in forming the different kinds of intercellular contacts, and differences in the morphological variability of the content of granules in the immunolabeled profiles. The results suggest diverse, non-synaptic modulatory roles of neuropeptides in the peripheral nervous system of Helix pomatia, including localized membrane effects and neurohormonal-like remote global controls, that may also be of significance in orchestrating the effects of neuropeptides released at the same time on different targets.

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.

Peripheral connections of FMRFamide-like immunoreactive neurons in the snail, helix pomatia: an immunogold electron microscopic study

Using a postembedding immunogold electron microscopic method, the ultrastructure and synaptic connections of FMRFamide-like immunoreactive varicosities were investigated in different peripheral organs of the snail Helix pomatia, including the heart (auricle), intestine, hepatopancreas, upper tentacle and salivary gland. The FMRFamide-like immunoreactive varicosities contained granules and vesicles as described in a previous study of the CNS of this species, and additionally, based on their granule content, two novel types of varicosities were found in the auricle. A selective accumulation of gold particles over the granules could be demonstrated. The FMRFamide-like immunoreactive varicosities formed unspecialized contacts with postsynaptic target cells in all peripheral organs investigated, with the exception of the tentacle retractor muscle. Both the neuro-muscular and the neuro-glandular contacts were characterized by either unspecialized close apposition of the 'pre- and postsynaptic' membranes or the immunoreactive elements faced the target cell(s) across a relatively wide extracellular space. In the tentacle retractor muscle some of the neuromuscular contacts showed appositions of electron dense material along the presynaptic membrane, clustering of agranular synaptic vesicles and intersynaptic cleft material. The present observations support previous electrophysiological findings and suggest a versatile modulatory role of FMRFamide and related substances in the Helix PNS.

Further characterization of Helix FMRFamide receptors: kinetics, tissue distribution, and interactions with the endogenous heptapeptides

The biphasic binding of 125I-daYFnLRFamide to crude brain membranes of Helix aspersa is due to two discernible sites (high and low affinity) rather than different agonist-induced states. The tissues in the snail that show the greatest specific 125I-daYFnLRFamide binding are the brain, reproductive system, and digestive system. The heart shows moderate binding levels, whereas low values are obtained in the oviduct and retractor muscles. The N-terminal SAR of the Helix heptapeptides (X-DPFLRFamide) indicates that, although the substitution of Leu for Met accounts for some, the dipeptide X-Asp produces most of the loss in potency at FMRFamide receptors in Helix brain.

Effects of biogenic amines and related agonists and antagonists on the isolated heart of the common cuttlefish Sepia officinalis L

1. Effects of noradrenaline and the related compounds adrenaline, dopamine, octopamine, tyramine, clonidine and isoprenaline were studied in isolated heart preparations from the cuttlefish Sepia officinalis L. 2. All analogues produced a positive inotropic affect, with noradrenaline being the most potent substance. The chronotropic effects of the tested compounds differed widely. 3. The action of substances of the phenylethanolamine group were not antagonized by propranolol but were partly antagonized by phentolamine. 4. Serotonin and its analogues also produced cardio-excitation. These effects were blocked by cyproheptadine but not by methysergide. 5. These results indicate the presence of two different receptors in the Sepia myocardium: one type reacting with noradrenaline most effectively and a second type being stimulated by serotonin.

Histochemical localization of cholinesterases and monoamines in the central heart of Sepia officinalis L. (Cephalopoda)

The central heart of the coleoid cephalopod, Sepia officinalis, was studied using acetylcholinesterase and fluorescence histochemistry. Using histo- and cytochemical reactions, acetylcholinesterase was localized in the axolemma and axoplasm of specific cardiac nerve fibres, as well as in the sarcolemma and within the sarcotubular system of the muscle cells. Butyrylcholinesterase exhibited a different distribution, being found only in the luminal trabecular muscle layer. Glyoxylic-acid-induced fluorescence indicated the presence of catecholamines (emission maximum, 470 nm) in cardiac nerve axons. These histochemical findings support the hypothesis that noradrenaline and/or dopamine and acetylcholine act antagonistically as natural transmitters. Fluorophores indicating the presence of serotonin were not observed. The present results are discussed in the light of previous pharmacological findings.

The distribution of bovine pancreatic polypeptide/FMRFamide-like immunoreactivity in the ventral nervous system of the locust

The distribution of bovine pancreatic polypeptide (BPP) FMRFamide-like immunoreactivity is described in the ganglia of the ventral nerve cord and in the peripheral median nervous system of the locust, Schistocerca gregaria. Immunoreactive cell bodies occur in three regions of the thoracic ganglia: 1) two pairs of cells lie in the anterior of the ganglion ventral to the root of nerve 1 and the anterior ventral association centre; 2) a group of cells lies in the ventral midline at the level at which nerves 3 and 4 leave the ganglion; 3) and two bilaterally symmetrical, posterior lateral groups lie between nerves 5 and 6 at the edge of the ganglion. Immunoreactive cell bodies in the suboesophageal and abdominal ganglia are confined to the midline and are distributed along the anterior-posterior axis both dorsally and ventrally. The processes of the posterior lateral groups have been traced into the neurohaemal organs of the median nerve and beyond. In the periphery such processes innervate the salivary glands and various muscles. The nature of the endogenous antigen contained in the immunoreactive cells has been investigated with the use of antisera against other peptides of the pancreatic polypeptide family, namely avian pancreatic polypeptide, neuropeptide Y, and peptide YY. In addition, BPP antisera not specific for the C terminal hexapeptide have been tested. Liquid preabsorption experiments with BPP and FMRFamide (the molluscan cardioacceleratory peptide) suggest that the endogenous peptide antigen contained in the stained neurones may belong to the pancreatic polypeptide family or to the FMRFamide family.

The axosomatic contacts on the bursting neuron of the snail Helix pomatia. I. Ultrastructural features of the axosomatic contacts

The analysis of serial ultrathin sections of the RPAI bursting neuron of the snail Helix pomatia reveals the presence of axosomatic contacts on its surface membrane. These contacts have a number of specific features: the presynaptic axon contains synaptic vesicles and electron-dense granules, typical of peptidergic terminals; the terminal part of the axon forms many finger-like processes which invaginate the neuronal soma; the width of the cleft (80 nm) in the area of the contact is larger than that in usual synaptic contacts; and there is a system of lacoons in the region of the axosomatic contact; this system is formed by protrusions of the soma and it accompanies the contact along its extent. It is suggested that the system of lacoons which communicates with the space between the terminal and the soma may serve as a ramified synaptic cleft into which the secretion from the terminal is released. This system may contribute to a considerable prolongation of the time of action of the secretory product on the membrane of the RPAI neuron.

The molluscan cardioactive neuropeptide FMRFamide: subcellular localization in bivalve ganglia

Ganglia of the mollusk Macrocallista nimbosa were pooled, homogenized, and subjected to differential centrifugation. The neuropeptide Phe-Met-Arg-Phe-NH2 (FMRFamide) was concentrated in the microsomal pellet. When the medium-speed supernatant was centrifuged in a discontinuous sucrose gradient, three separate peaks of activity were detected and identified as acetylcholine, 5-hydroxytryptamine, and FMRFamide. The relative concentration of FMRFamide in each fraction was determined by bioassay and by radioimmunoassay (RIA). Both determinations revealed a peak of peptide in the middle of the sucrose gradient. Electron micrographs of each of the gradient interfaces were analyzed. The interface containing the peak of biological FMRFamide activity was enriched in two- to fivefold in neurosecretory granules with a mean diameter of 104 nm and various electron densities. Morphologically similar vesicles were also seen in intact ganglia. These findings support the notion that FMRFamide is a neurosecretory product. But the physiological function of the peptide in bivalve ganglia remains unknown.

Motor innervation of the pharynx levator muscle of the snail, Helix pomatia: physiological and histological properties

(1) Motor innervation of the pharynx levator muscle of Helix pomatia was investigated with intracellular recording and axonal iontophoresis of cobalt chloride. (2) Muscle fibers respond to direct electrical stimulation of the muscle with active graded responses or non-overshooting spike potentials. (3) Each fiber is innervated via the external and internal lip nerves by several (mostly 3) excitatory nerve fibers each. Two types of EPSPs can be distinguished according to amplitude, duration, and facilitation. (4) Axonal CoCl2-staining via an external lip nerve branch revealed many nerve fibers entering the muscle and branching there into a rich network of blebbed fibers of various diameters.

The anatomy of neurosecretory neurones in the pond snail Lymnaea stagnalis (L.)

The anatomy of three neurosecretory cell types in the central nervous system (c.n.s.) of the gastropod mollusc Lymnaea stagnalis (L.)- the Dark Green Cells, Yellow Cells and Yellow-green Cells-has been studied by using bright and dark field illumination of material stained for neurosecretion by the Alcian Blue-Alcian Yellow technique. The neuronal geometry of single and groups of neurosecretory cells of the various types has been reconstructed from serial sections, and the likely destination of most of their processes has been determined. Dark Green Cells are monopolar, occur exclusively within the central nervous system (c.n.s.), have few or no branches terminating in neuropile, and send axons to the surface of the pleuro-parietal and pleuro-cerebral connectives. The majority of Dark Green Cell axons however (80-85%), project down nerves which innervate ventral and anterior parts of the head-foot, the neck and the mantle. Dark Green Cell axons can be found in small nerves throughout these areas, and may terminate in a find plexus of axons on the surfaces of the nerves. Since previous experimental work has shown that the Dark Green Cells are involved in osmotic or ionic regulation, these results suggest that the target organ of the Dark Green Cells may be the skin. Yellow Cells occur both within and outside the c.n.s. They are usually monopolar, but can be bipolar. They have several axons which normally arise separately from a single pole of the cell body, or close to it. One or more processes leave the cell proximal to the point where separate axons arise, and may run unbranched for some distance through neuropile before terminating in fine brances and blobs of various sizes. These branches may release hormone inside the c.n.s. Yellow-green Cells are mono-, bi- or multi-polar, and like the Yellow Cells are found both within and outside the c.n.s. Some Yellow-green Cells, though not all, have projections which terminate in neuropile in fine branches and blobs. Yellow-green Cell bodies which occur in nerves can project back along the nerve into the c.n.s. The axons of Yellow Cells and Yellow-green Cells project to release sites in various ways. Some project into the connective tissue shealth of the c.n.s., which serves as a neurohaemal organ, either directly through the surface of a ganglion, or from the pleuro-cerebral or pleuro-parietal connectives. Other axons leave the c.n.s. via nerves leaving the left and right parietal and visceral ganglia; projections into the intestinal, anal, and internal right parietal nerves being most numerous. Axons which may be from either, or both Yellow Cells and Yellow-green Cells, can be found along the entire unbranched lengths of these nerves, and in subsequent branches which innervate organs lying in the anterior turn of the shell. All of these orgnas are closely associated with the lung cavity...