The bioelectrical activity of the body wall of the pulmonate freshwater snail Lymnaea stagnalis: effects of neurotransmitters and the sodium influx stimulating neuropeptides

Homeostatic regulation in physiological systems: A versatile Ansatz

A generic modelling formalism is described for homeostatic dynamics in physiological systems. The method is particularly suited where the peripheral, physiological system itself is well-characterised, but the details of the central, regulatory component (the nervous and endocrine systems) have not necessarily been characterised in full detail. The method is applied to temperature regulation in Cardinalis cardinalis, C. sinuatus, Lepus alleni, and Passer domesticus, and furthermore to hydromineral regulation in Lymnaea stagnalis. These case studies demonstrate that the method allows a comprehensive analysis and integration of the available data and is capable of furnishing physiologically relevant predictions. We discuss the method in relation to optimal control theory as well as more conventional modelling approaches.

Annelid epithelia as models for electrogenic Na+ transport

The electrogenic Na(+) absorption across tight epithelia from invertebrates follows the principles analog to the mechanisms found in vertebrates. Extracellular Na(+)-ions pass the apical cell membranes through highly selective Na(+) channels and follow an electrochemical gradient which is sustained by the basolateral Na(+)/K(+)-ATPases. These apical Na(+) channels are selectively blocked by amiloride and represent the rate-limiting target for the control of transcellular Na(+) uptake. Although annelids express ADH-like peptide hormones, they lack the osmoregulatory mineralocorticoid system with the vertebrate-specific key hormone aldosterone. Thus, their epithelia may represent interesting models for investigation of ion transport regulation. While the formation of urine in the nephridia of, for example, leeches had been subject to intensive studies, the investigation of ion transport across their body wall was largely neglected. We use dissected segments of integuments from the limnic leech Hirudo medicinalis and, recently, from the earthworm Lumbricus terrestris for Ussing chamber experiments. We investigate transintegumental ion transport with focus on control of electrogenic Na(+) uptake and the amiloride-sensitive part of it and identified several extracellular factors as peptide hormones, tri- and divalent cations or purinergic molecules with regulatory effects on it. Meanwhile, there exists a macroscopic view on Na(+) absorption; however, other ion transport mechanisms across annelid integuments still await scientific effort. Here we present a concise synopsis about the electrophysiology of annelid integuments to illustrate the state of science and to evaluate whether further studies in this particular field may be of interest.

Regulation of Na(+) transport across leech skin by peptide hormones and neurotransmitters

An increase in intracellular cyclic AMP concentration stimulates transepithelial Na(+) transport across the skin of the leech Hirudo medicinalis, but it is unclear how cytosolic cyclic AMP levels are elevated in vivo. In search of this external stimulus, we performed Ussing chamber experiments to test several peptide hormones and neurotransmitters for their effect on Na(+) transport across leech dorsal integument. Although all the peptide hormones under investigation significantly affected ion transport across leech integument, none of them mimicked the effect of an experimental rise in intracellular cyclic AMP level. The invertebrate peptides conopressin and angiotensin II amide inhibited short-circuit-current- (I(sc)) and amiloride-sensitive Na(+) transport (I(amil)), although to slightly different degrees. The vertebrate peptide hormones 8-arginine-vasopressin and 8-lysine-vasopressin both produced an inhibition of I(amil) comparable with that caused by angiotensin II amide. However, 8-lysine-vasopressin reduced I(sc), whereas 8-arginine-vasopressin induced a moderate increase in I(sc). The neurotransmitter dopamine, which occurs in the leech central nervous system in relatively large amounts, and its precursor l-dopamine both induced large decreases in I(sc) and I(amil). However, the reactions evoked by the catecholamines showed no pronounced similarity to the effects of intracellular cyclic AMP. Two other neurotransmitters known to occur in leeches, serotonin (5-hydroxytryptamine) and gamma-n-aminobutyric acid (GABA), had no influence on transepithelial ion transport in leech skin.

cDNA cloning of the sodium-influx-stimulating peptide in the mollusc, Lymnaea stagnalis

We isolated and characterized a cDNA clone, encoding the prohormone of the sodium-influx-stimulating (SIS) peptide of the freshwater snail Lymnaea stagnalis. The prohormone is cleaved to generate a signal peptide of 23 amino acids and a SIS peptide of 77 amino acids. The SIS peptide as encoded by the cDNA represents a novel and complex neuropeptide, which controls the activity of sodium pumps in the integument, pericardium, ureter and nephridial gland. In situ hybridization showed that the SIS-peptide gene is expressed by the neuroendocrine, so-called Yellow Cells of the central nervous system.

The sodium influx stimulating peptide of the pulmonate freshwater snail Lymnaea stagnalis

In Lymnaea stagnalis integumental Na+ uptake is stimulated by the sodium influx stimulating (SIS)-peptide. Its primary structure was determined as: SRTQSRFAS- YELMGTEGTECVTTKTISQICYQCATRHEDSFVQVYQECCKKEMGLREYCEEIYTELPIRSGLWQPN++ +. Antisera raised against parts of SIS-peptide stained neurons in the visceral, parietal, and pleural ganglia, and in the proximal parts of the intestinal, anal, and right internal pallial nerves. Locations and axon projection patterns of these neurons suggest that they represent the previously described neurosecretory yellow cells.

Some polypeptides in the nervous system of the marine worm, Nereis diversicolor, are related to the sodium influx stimulating peptide of the pulmonate freshwater snail, Lymnaea stagnalis

Total mRNA, extracted from brain of the marine worm, Nereis diversicolor (Annelida, Polychaeta), was translated either in vitro using a rabbit reticulocyte lysate or in ovo (Xenopus laevis oocyte). The synthesized polypeptides were analyzed by electrophoresis and Western blotting techniques using polyclonal antisera raised against three peptides: sodium influx stimulating peptide (SISP) sequences 10-19 and 67-76 and a monoclonal antibody raised against purified native SISP (1-77) of Lymnaea stagnalis. Among the products translated in vitro, three polypeptides of 80, 72, and 64 kDa were recognized by the anti-SISP (10-19) polyclonal antiserum and by the monoclonal antiserum, but not by anti-SISP (67-76). Some of the in ovo translated products showed almost identical immunoreactivity to both the anti-SISP (10-19) and the monoclonal antibody. These polypeptides have molecular masses of 80, 72, and 43 kDa. No polypeptides were recognized by anti-SISP (67-76). Western blotting analysis of brain extracts revealed a number of proteins that reacted with the antiserum raised against SISP (10-19) and the monoclonal antiserum. Several perikarya of brain ganglionic nuclei and ventral nerve cord were immunoreactive to anti-SISP (10-19). The monoclonal antiserum gave similar results, although with a less intense immunoreaction. The infracerebral region was also stained, suggesting that the immunoreactive material is released as a true neurohormone into the hemolymph. The largest polypeptides, in particular those translated from brain mRNA, could be neuropeptide precursors containing a SISP-related sequence.

Differential expression of four genes encoding molluscan insulin-related peptides in the central nervous system of the pond snail Lymnaea stagnalis

In the pond snail Lymnaea stagnalis, the growth regulating system consists of (1) about 200 neuroendocrine light green cells, located in four clusters in the cerebral ganglia, and (2) the paired canopy cells, located in the lateral lobes. These cells express genes encoding the molluscan insulin-related peptides (MIPs). Six MIP genes have previously been identified. Four of these (I, II, III and V) are expressed in the light green cells and the canopy cells. The MIP-VI gene is a pseudogene. In the present in situ hybridization study, using oligonucleotide probes specific to the transcripts of MIP-I, -II, -III, -IV and -V, no signal was obtained with the MIP-IV probe, indicating that gene IV is also a pseudogene. With the other four probes, two types of light green cells were distinguished. Type-A cells express all four MIP genes, whereas type-B cells do not (or only faintly) express the MIP-I gene. Gene III is relatively strongly expressed in type-B cells. Genes II and V are moderately expressed in both cell types. Type-A cells are mainly located in the periphery of the clusters, whereas type-B cells are present in the center. The canopy cell resembles type-A light green cells. The expression levels of the MIP-II and MIP-V genes are low in the canopy cell. The expression pattern of the MIP genes correlates with the staining pattern of the anti-MIP-C antibody, which has been raised to a synthetic C-fragment shared by MIP-I, -II and -V. Type-A cells stain more intensely with the antibody than type-B cells.

Functional morphology of the neuroendocrine sodium influx-stimulating peptide system of the pond snail, Lymnaea stagnalis, studied by in situ hybridization and immunocytochemistry

The functional morphology of the neuroendocrine system producing sodium influx-stimulating (SIS) peptide in the pond snail, Lymnaea stagnalis, was studied by in situ hybridization and immunocytochemistry. The SIS-peptide, which is 76 amino acids long, stimulates sodium uptake from the ambient medium. Two synthetic DNA probes were used for in situ hybridization. The nucleotide sequences were chosen from the cDNA structure; they encode amino acids 8-17 and 64-73, respectively. SIS-peptide sequences 10-20 and 67-76 were synthesized and antibodies were raised to them and affinity-purified. In addition to these antibodies, a monoclonal antibody raised to a bioactive, high-pressure liquid chromatography (HPLC)-purified brain extract was used for immunocytochemistry. Paraffin sections of central nervous systems and of whole snails were studied. The SIS-peptide system could be identified as the previously described yellow cell (YC) system by comparing alternate sections treated with the DNA probes, stained with the antibodies, or stained with alcian blue-alcian yellow. SIS-peptide neurons (approximately 45) occur in the ganglia of the visceral ring and in the proximal parts of visceral nerves. Axons run in the nerves of these and in several nerves of other ganglia. Numerous axon branches penetrate the perineurium forming a vast central neurohemal area. The SIS-peptide system innervates the pericardium, the nephridial gland, the reno-pericardial canal, the ureter, the spermoviduct and gonadal acini, the anterior aorta, the ventral buccal artery, and the penis protractor muscle.(ABSTRACT TRUNCATED AT 250 WORDS)

Ultrastructural evidence for synthesis, storage and release of insulin-related peptides in the central nervous system of Lymnaea stagnalis

The cerebral neuroendocrine Light Green Cells of the pulmonate snail Lymnaea stagnalis, which control body growth and associated processes, stain positively with an affinity-purified antiserum raised to a large part of the C-chain of pro-molluscan insulin-related peptides. At the ultrastructural level, the rough endoplasmic reticulum is immunonegative, the Golgi apparatus is slightly positive and secretory granules in the process of budding from the Golgi apparatus are strongly positive. These observations indicate that the Light Green Cells synthesize molluscan insulin-related peptides, which are processed before packing by the Golgi apparatus into secretory granules. The two morphologically distinct secretory granule types, i.e. with pale and dark contents, respectively, are equally immunoreactive with antiserum raised to the C-chain of molluscan insulin-related peptides. Secretory granules within lysosomal structures reveal various degrees of immunoreactivity, indicating their graded breakdown. The Light Green Cells release secretory material by the process of exocytosis into the haemolymph from neurohaemal axon terminals located in the periphery of the median lip nerve. The electron-dense (tannic acid method) released contents are clearly immunopositive. The same holds for secretory granule contents released from Light Green Cells axon profiles in the centre of the lip nerve. Some immunoreactivity is also present in the intercellular space between these axon profiles. It is concluded that molluscan insulin-related peptides may act in two ways, namely (1) as neurohormones via the haemolymph at peripheral targets and (2) in a non-synaptic (paracrine) fashion at targets within the central nervous system.