Neurogenesis in the mossy chiton,Mopalia muscosa (Gould) (Polyplacophora): evidence against molluscan metamerism

Neurogenesis in the chiton Mopalia muscosa (Gould, 1846) was investigated by applying differential interference contrast microscopy, semithin serial sectioning combined with reconstruction techniques, as well as confocal laser scanning microscopy for the detection of fluorescence-conjugated antibodies against serotonin and FMRFamide. The ontogeny of serotonergic nervous structures starts with cells of the apical organ followed by those of the cerebral commissure, whereas the serotonergic prototroch innervation, pedal system, and the lateral cords develop later. In addition, there are eight symmetrically arranged serotonergic sensory cells in the dorsal pretrochal area of the larva. FMRFamide-positive neural elements include the cerebral commissure, specific "ampullary" sensory cells in the pretrochal region, as well as the larval lateral and pedal system. In the early juvenile the cerebral system no longer stains with either of the two antibodies and the pedal system lacks anti-FMRFamide immunoreactivity. Outgroup comparison with all other molluscan classes and related phyla suggests that the cord-like, nonganglionized cerebral system in the Polyplacophora is a reduced condition rather than a primitive molluscan condition. The immunosensitivity of the pedal commissures develops from posterior to anterior, suggesting independent serial repetition rather than annelid-like conditions and there is no trace of true segmentation during nervous system development. Polyplacophoran neurogenesis and all other available data on the subject contradict the idea of a segmented molluscan stem species.     

Cellular Neuronal Control of Molluscan Heart

Bivalve and gastropod molluscs undergo large changes in externalenvironmental conditions, as well as in internal state. Cardiacresponses to these changing conditions have been recorded ina variety of species. There is a general tendency for heartrate, and presumably cardiac output, to increase in responseto situations that would increase the load on respiratory andexcretory systems. Changes in molluscan heart function in manycases appear not to be mediated directly by cardiac nerves,but rather by such indirect mechanisms as changes in blood constituentsor mechanical, hemodynamic effects on heart muscle. Three typesof cardiac response in Aplysia have been shown to be mediated,at least in part, by the heart regulator nerves. The neural circuits that regulate heart rate in Aplysia andin Helix have been partially described in cellular detail. InMercenaria, Aplysia and other molluscan species there is evidencethat cyclic adenosine monophosphate has a role in mediatingthe excitatory effects of serotonin on heart muscle. There appearsto be, in fact, a general tendency in the Aplysia nervous systemfor neurons that exert tonic, modulatory effects within neuralnetworks that control a variety of behaviors to use serotoninfor a transmitter. In each case there is evidence to suggestthat changes in cyclic adenosine monophosphate levels may mediatesome of the modulatory effects of serotonin.     

Aminergic cellular organization in the gills of Aplysia species

The constituent elements of the gills of Aplysia kurodai and A. juliana were examined for the presence of biogenic amines using histochemical, immunocytochemical, and HPLC techniques. Aminergic elements were revealed by glyoxylic acid-induced fluorescence in the branchial nerve, branchial ganglion, branchial vessels, and pinnules in both species. Three types of fluorescent cells were found in the neural plexus of the gill in each species. Two of them might be sensory neurons. Although HPLC analysis showed the presence of serotonin and dopamine in all gill structures including fluorescent neural elements, there were regional differences in concentrations of the monoamines. It was noted in the pinnules that there was a much higher concentration of dopamine than serotonin. Serotonin immunocytochemistry revealed neural processes which were immunoreactive to antiserotonin antibody, but serotonin immunoreactivity could not be found in a population of branchioganglionic neuron (BGN) somata. Serotonergic elements in the ganglion may be processes of the central ganglion, while dopaminergic elements may be processes of neurons in the neural plexus, located beyond the branchial ganglion. BGNs were activated by bath-applied dopamine and serotonin. These results suggest that dopaminergic sensory inputs from the neural plexus and serotonergic descending inputs from the abdominal ganglion may be among the inputs received by BGNs. It was found that serotonin depressed excitatory junctional potentials in muscle cells of the efferent branchial vessel, which were induced by an identified neuron of the abdominal ganglion. The aminergic cellular organization of the gill may involve serotonergic presynaptic-inhibitory fibers arising from the abdominal ganglion.     

Molecular characterization of NOS in a mollusc: Expression in a giant modulatory neuron

Here we report on the molecular characterization of the first molluscan NOS in the CNS of the pond snail Lymnaea stagnalis. This Lymnaea NOS (Lym-nNOS) which is expressed preferentially in the CNS is most similar to mammalian neuronal NOS but contains tandem repeats of a seven amino acid motif not found in any other known NOS. We have localized Lym-nNOS to the serotonergic cerebral giant cells (CGCs) which modulate synaptic transmission within a neural network that generates feeding behavior. Our results suggest that the CGCs employ both NO and serotonin in the modulation of the central neural network underlying feeding. © 1998 John Wiley & Sons, Inc. J Neurobiol 35: 65–76, 1998     

Serotonergic cerebral cells control activity of cilia in the foregut of the pteropod mollusk <Emphasis Type="Italic">Clione limacina</Emphasis>

Bilaterally symmetrical pair of serotonergic cells, named C1 in Clione, has been described in the cerebral ganglia of all gastropod species. Here we describe a new role of C1 cells in gastropod mollusks: control of activity of ciliated epithelium in the foregut. Detailed morphological investigation of C1 neurons in the pteropod mollusk Clione limacina revealed that these cells among other destinations send their neurites into foregut where they produce intense arborization with large varicosities along the processes. Intracellular stimulation of a single C1 induced pronounced activation (often followed by inhibition) of cilia lining the foregut. This activation was substantially reduced by serotonin antagonist mianserin. Bath application of serotonin also induced transient increase in ciliary transport rate, followed by inhibition of ciliary activity up to its full cessation in some areas of isolated foregut. These data suggest that C1 in Clione may use serotonin to influence cilia in the foregut. Taking into account high homology of serotonergic cerebral cells across studied species we can speculate that these cells may be involved in the neural control of cilia in the foregut in other gastropod mollusks.     

An identified serotonergic neuron regulates adult neurogenesis in the crustacean brain

New neurons are born and integrated into functional circuits in the brains of many adult organisms. In virtually all of these systems, serotonin is a potent regulator of neuronal proliferation. Specific neural pathways underlying these serotonergic influences have not, however, been identified and manipulated. The goal of this study was to test whether adult neurogenesis in the crustacean brain is influenced by electrical activity in the serotonergic dorsal giant neurons (DGNs) innervating the primary olfactory processing areas, the olfactory lobes, and higher order centers, the accessory lobes. Adult‐born neurons occur in two interneuronal cell clusters that are part of the olfactory pathway. This study demonstrates that neurogenesis also continues in these areas in a dissected, perfused brain preparation, although the rate of neuronal production is lower than in brains from intact same‐sized animals. Inclusion of 10^?9 M serotonin in the perfusate delivered to the dissected brain preparation restores the rate of neurogenesis to in vivo levels. Although subthreshold stimulation of the DGN does not significantly alter the rate of neurogenesis, electrical activation of a single DGN results in significant increases in neurogenesis in Cluster 10 on the same side of the brain, when compared with levels on the contralateral, unstimulated side. Measurements of serotonin levels in the perfusate using high‐performance liquid chromatography established that serotonin levels are elevated about 10‐fold during DGN stimulation, confirming that serotonin is released during DGN activity. This is the first identified neural pathway through which adult neurogenesis has been directly manipulated. © 2009 Wiley Periodicals, Inc. Develop Neurobiol 2009     

Dopaminergic acceleration and GABAergic inhibition in extrinsic neural control of the hermit crab heart

The acceleratory and inhibitory cardio-regulatory nerves of hermit crabs (Aniculus aniculus, Dardanus crassimanus) were studied using histochemical, immunocytochemical and pharmacological tests. Glyoxylic acid-induced fluorescence was observed in two of three axons of the dorsal cardiac nerve. One axon of the nerve showed gamma-aminobutyric acid-like immunoreactivity. Effects of stimulation of cardio-acceleratory axons were blocked by the dopaminergic antagonists, haloperidol and chlorpromazine, but not by cholinergic, adrenergic or serotonergic blockers, suggesting that dopamine is the primary potential candidate for the neurotransmitter of cardio-accelerator neurons. Picrotoxin antagonized inhibition of the cardiac ganglion induced by gammaam-inobutyric acid and by cardio-inhibitory axons. Both small and large ganglionic cells may receive dopaminergic and GABAergic extrinsic neural control.Abbreviations ACh acetylcholine - CA cardio-accelerator - CA1 and CA2 first and second cardio-accelerators - CI cardio-inhibitor - EJP excitatory junction potential - GABA gamma-aminobutyric acid - EPSP excitatory postsynaptic potential - IPSP inhibitory postsynaptic potential - LGC large ganglionic cell - SGC small ganglionic cell - 5-HT serotonin     

DETECTION OF A SOLUBLE SEROTONIN-BINDING PROTEIN IN THE MAMMALIAN MYENTERIC PLEXUS AND OTHER PERIPHERAL SITES OF SEROTONIN STORAGE

Groups of neurons intrinsic to the mammalian myenteric plexus have been shown to have both tryptophan hydroxylase and a specific uptake mechanism for serotonin. They are probably serotonergic. A soluble protein with a high binding affinity for serotonin, similar to a protein previously found in rat brain by TAMIR & HUANG (1974), has now been found in the myenteric plexus of both rabbit and guinea pig. Partial purification of the protein from the rabbit's myenteric plexus by ammonium sulfate fractionation increased the ratio of specific to nonspecific serotonin binding almost 3-fold. Two dissociation constants for serotonin binding were obtained by equilibrium dialysis: 6.7 × 10^?10 M and 4.8 × 10^?7 M. The protein was similar to the soluble serotonin-binding protein of CNS: the indole derivatives 5, 6- and 5, 7-dihydroxytryptamine, and 6-hydroxytryptamine inhibited serotonin binding by 50% at 10^?7 M; norepinephrine was a poor inhibitor of serotonin binding; most of the serotonin-protein complex had a very high molecular weight and did not penetrate a 6.5% acrylamide gel. The appearance of the serotonin binding protein during development of the intestine in fetal rabbit correlates closely with the development of a serotonin uptake mechanism by nerves of this tissue and precedes the ingrowth of the adrenergic innervation. In-vitro administration of 6-hydroxydopamine to adult animals has no effect on the binding capacity for serotonin. Binding activity in denervated preparations is only 1/5 that of innervated tissue. It is concluded that the serotonin-binding protein, which has been found associated with serotonergic pathways in the CNS, is found associated with serotonergic neurons in the periphery as well. Since a similar serotonin-binding protein is also found in sheep thyroid, which stores but does not take up serotonin, the protein may be a component of the serotonin storage mechanism.     

Performance of the isolated and perfused working heart of the teleostConger conger: study of the inotropic effect of prostacyclin

Summary An in vitro preparation of the heart of the teleostConger conger, isolated without the pericardium, was set up. The procedure allowed subambient pressures to develop in the perfusion chamber during contraction, mimicking the in vivo situation with the pericardium intact. The ventricle produced a cardiac output of about 15 ml·min^-1·kg wet body weight^-1 at subambient input pressure, and was able to double the stroke work with an increase of preload up to about 0.2 kPa. Using this preparation it was found that prostacyclin has a positive inotropic effect on the atrium and ventricle, but it does not affect the heart rate. Semilogarithmic doseresponse curves of prostacyclin on the atrium are reported, showing a threshold concentration of about 10^-9 M. The isolated and perfusedConger conger heart provides a useful model for a detailed analysis of the action of prostacyclin on myocardial contractility.     

Biogenic amines modulate synaptic transmission between identified giant interneurons and thoracic interneurons in the escape system of the cockroach

In the escape system of the cockroach, Periplaneta americana, a population of uniquely identifiable throacic interneurons (type A or TI_As) receive information about wind via chemical synapses from a population of ventral giant interneurons (vGIs). The TI_As are involved in the integration of sensory information necessary for orienting the animal during escape. It is likely that there are times in an animal's life when it is advantageous to modify the effectiveness of synaptic transmission between the vGIs and the TI_As. Given the central position of the TI_As inthe escape system, this would greatly alter associated motor outputs. We tested the ability of octopamine, serotonin, and dopamine to modulate synaptic transmission between vGIs and TI_As. Both octopamine and dopamine significantly increased the amplitude of vGI-evoked excitatory postsynaptic potentials (EPSPs) in TI_As at 10^?4?10^?2 M, and 10^?3 M, respectively. On the other hand, serotonin significantly decreased the vGI-evoked EPSPs in TI_As at 10^?4?10^?3 M. These results indicate that octopamine, serotonin, and dopamine are capable of modulating the efficacy of transmission of important neural connections within this circuit. © 1992 John Wiley & Sons, Inc.     

Serotonergic Actions and Interactions on the SCN Circadian Pacemaker: In Vitro Investigations

The phase of the mammalian circadian pacemaker located in the suprachiasmatic nuclei (SCN) is controlled by a multitude of stimuli. While phase control is undoubtedly dominated by photic input, the serotonergic input from the raphe nuclei also influences SCN clock phase. In this article I review the evidence for serotonergic modulation of the SCN pacemaker, and the cellular mechanisms underlying these effects, obtained from in vitro experiments performed during the past decade. Serotonin can advance the SCN pacemaker when applied during the subjective day, and delay the pacemaker when applied during the subjective night. The daytime advances appear due to stimulation of 5HT₇ receptors, activation of adenylate cyclase and protein kinase A, and opening of K⁺ channels. The synthesis of new proteins may also be critical for these phase shifts. Serotonergic phase advances can be inhibited by a variety of other modulatory inputs to the SCN, including neuropeptide Y, melatonin, and glutamate. Together, these data demonstrate that SCN circadian pacemaker phase is controlled by a complex interplay between multiple afferent stimuli, and that serotonin plays a critical role in this process.     

The Nervous System of Early Larval Stages of the Cestode Diphyllobothrium dendriticum

The nervous system (NS) of the coracidium and procercoid larval stages of the pseudophyllidean cestode Diphyllobothrium dendriticum was examined by whole mount immunocytochemistry and electron microscopy. Antisera against the bioamine serotonin and the molluscan cardioexcitatory peptide FMRF-amide gave a positive immunoreaction in the NS of the procercoid. Ultrastructurally, three types of nervous elements were discerned. Ultrastructural evidence of both aminergic and peptidergic neurons in the coracidium is provided. The NS of these early larval stages is simply organized. The serotonergic part of the NS shows a beginning centralization in the procercoid, while the peptidergic neurons are more peripherally distributed.     

Oxidative stress,serotonergic changes and decreased ultrasonic vocalizations in a mouse model of Smith–Lemli–Opitz syndrome

Smith–Lemli–Opitz syndrome is an inherited monogenic disorder in which mutations to the 7‐dehydrocholesterol (7‐DHC) reductase (Dhcr7) gene lead to deficits in cholesterol synthesis. As a result, many patients suffer from gross physiological and neurological deficits. The purpose of this study was to identify a potential abnormal behavioral phenotype in a compound mutant mouse model for Smith–Lemli–Opitz disease (Dhcr7 ^{Δ3 –5/ T93M} ) to further validate the model and to provide potential targets for future therapeutic interventions. We also sought to identify some of the underlying changes in brain function that may be responsible for behavioral differences among groups. The Dhcr7 compound mutant mice were smaller than their single mutant littermates. Both single and compound heterozygous mice made fewer ultrasonic vocalizations when separated from the dam, which may suggest a communication deficit in these animals. Striking increases of the highly oxidizable 7‐DHC were observed in the compound mutant mice. 7‐Dehydrocholesterol is the precursor to cholesterol and builds up because of decreased function of the mutated Dhcr7 enzyme. Additionally, several differences were noted in the serotonergic system including increased expression of the serotonin transporter and increased uptake of serotonin by isolated synaptosomes. We propose that changes to the oxidative environment during development can have a significant impact on the development of serotonergic function and that this contributes to behavioral differences observed in the mutant mice.     

Effects of serotonin on the cardio-circulatory system of the European eel (Anguilla anguilla) in vivo

The effects of serotonin on continuously recorded cardiac parameters (heart rate, cardiac output, cardiac stroke volume), ventral and dorsal aortic blood pressures, branchial and systemic vascular resistances were investigated in the European eel in vivo. Intravenous administration of serotonin (30 g · kg^–1) caused a marked bradycardia (45%) and a simultaneous decrease in cardiac output (50%), ventral (35%) and dorsal (50%) aortic blood pressures. Branchial resistance was markedly increased (60%) and systemic resistance decreased (30%). Cardiac stroke volume remained unchanged. The effects of serotonin on cardiac mained unchanged. The effects of serotonin on cardiac parameters were suppressed either by methysergide or a bilateral section of the cardiac vagus. Bradycardia could then be regarded as the consequence of a vagal mechanism triggered by serotonin action on central methysergide-sensitive serotonergic receptors. No inotropic effect of serotonin was observed. This lack of myocardiac contractility modification is discussed. The serotonin-mediated branchial vasoconstriction was attenuated by vagotomy, whereas the residual increase in branchial resistance (40%) was suppressed by methysergide. The serotonin-mediated branchial vasoconstriction could be the consequence of both a passive mechanism (compliance) caused by the decrease in cardiac output and an active mechanism involving methysergide-sensitive serotonergic receptors of the branchial vasculature. A possible involvement of this vasomotor effect in gill oxygen uptake is discussed. The serotonin-induced systemic vasodilation was insensitive either to cardiac vagotomy or to 5-HT_1/2, 5-HT₃ and 5-HT₄ receptor antagonists, suggesting the involvement of a local mechanism which remains to be assessed.Abbreviations CSV cardiac stroke volume - DAP dorsal aortic pressure - HR heart rate - QC cardiac output - VAP ventral aortic pressure - VR _b branchial vascular resistance - VR _s systemic vascular resistance - VR _t total vascular resistance - 5-HT 5-Hydroxytryptamine serotonin - RBI Research Biochemical Incorporated, metoclopramide HCl     

The Role of Serotonin in Tritonia diomedea

The within-swim pattern of cycle periods in Tritonia swimmingchanged when the behavior was repeatedly elicited suggestingthat an excitatory process reaches a ceiling or wanes over repeatedtrials. Exposure to subthreshold stimuli enhanced swimming inresponse to a subsequent super-threshold stimulus, perhaps usinga similar excitatory process. In reduced preparations, subthresholdstimuli increased action potential activity in identified serotonergicneurons. Finally, stimulating serotonergic neurons enhanceda fictive swimming pattern, much like subthreshold stimuli enhancedthe swimming behavior. Both within-swim and across-swim changesin the swimming behavior may be caused by increased activityin identified serotonergic neurons. Comparative study suggeststhat ancestral serotonergic systems facilitated network oscillationsfor the production of rhythmic behaviors such as feeding andlocomotion. This concept of serotonin as oscillatizer is usedto explain the role of serotonergic neurons in Tritonia. Implicationsfor human mental health are discussed.     

Receptor of Insulin-Like Growth Factor 1 in Tissues of the Mollusc Anodonta cygnea

To identify insulin-like receptors in the mollusc Anodonta cygnea, specific binding of ¹²⁵I-insulin and ¹²⁵I-IGF-1 by WGA-purified glycoprotein fractions of foot muscles and neural ganglia is studied. The binding sites for IGF-1 are detected for the first time in invertebrates, both in the muscles, and in the neural tissue of the mollusc. The level of ¹²⁵I-IGF-1 binding in the muscle tissue was equal to 2.8 ± 0.1, in the neural tissue, to 4.0 ± 0.2% per 5 µg of protein. The equilibrium dissociation constant (K _d) was equal to 4.8 ± 0.3 and 4.3 ± 0.2 nM, respectively. The relative affinity of the binding sites to insulin did not exceed 1% of their affinity to IGF-1. Binding of ¹²⁵I-insulin in the muscle tissue was not detected; the level of labeled insulin binding in the neural tissue was equal to 0.5% per 5 µg of protein. In the sarcolemmal fraction of the mollusc foot, IGF-1 and, to a lesser degree, insulin at a dose of 100 nM initiated phosphorylation of tyrosine in a protein with mol. mass of 70 kDa. The minor band of the phosphorylation was also detected in the zone of protein of 80 kDa. The conclusion is made about the existence in molluscan tissues of high-conserved receptors-tyrosine kinases identical by functional parameters to the mammalian receptor of IGF-1. From this, it is suggested that the peptides close by structure to vertebrate IGF-1 may be involved in physiological processes in A. cygnea. The problem of the nature of the insulin-binding sites in the molluscan neural tissue is discussed.     

Serotonin in the developing stomatogastric system of the lobster,Homarus americanus

We studied the development of the serotonergic modulation of the stomatogastric nervous system of the lobster, Homarus americanus. Although the stomatogastric ganglion (STG) is present early in embryonic development, serotonin immunoreactivity is not visible in the STG until the second larval stage. However, incubation of the STG with exogenous serotonin showed that a serotonin transporter is present in embryonic and early larval stages. Serotonin uptake was blocked by paroxetine and 0% Na⁺ saline. The presence of a serotonin transporter in the embryonic STG suggests that hormonally liberated serotonin could be taken up by the STG, and potentially released as a “borrowed transmitter”. Consistent with a potential hormonal role, serotonin is found in the pericardial organs, a major neurosecretory structure, by midembryonic development. The rhythmic motor patterns produced by embryonic and larval STGs were decreased in frequency by serotonin. Lateral Pyloric (LP) neuron‐evoked excitatory junctional potentials (EJPs) in the embryos and the first larval stage (LI) were larger, slower, and more variable than those in the adult. The amplitude of adult LP neuron‐evoked EJPs was increased more than twofold in serotonin, but in embryos and LI preparations this effect was negligible. In embryos and LI preparations, serotonin increased the occurrence of muscle fiber action potentials and altered the EJP wave‐form. These data demonstrate that serotonin receptors are present in the stomatogastric nervous system early in development, and suggest that the role of serotonin changes from modulation of muscle fiber excitability early in development to enhancement of neurally evoked EJPs in the adult. © 2002 Wiley Periodicals, Inc. J Neurobiol 54: 380–392, 2003     

The origins of molluscs

The interrelationships and evolutionary history of molluscs have seen great advances in the last decade. Recent phylogenetic studies have allowed alternative morphology‐based evolutionary scenarios to be tested and, most significantly, shown that the aplacophorans are sister group to polyplacophorans (chitons), corroborating palaeontological and embryological evolutionary scenarios in which aplacophorans are secondarily simplified from a chiton‐like ancestor. Aplacophoran morphology therefore does not represent the plesiomorphic condition for molluscs as a whole. The mollusc crown group radiated in the Early Cambrian, and rapidly thereafter, stem lineages to the major molluscan classes emerged: cephalopods, gastropods, bivalves (= pelecypods), monoplacophorans, rostroconchs (inferred stem scaphopods) and aculiferans. This attests to the fast, adaptive radiation of the crown group during the Cambrian explosion. Kimberella from the latest Ediacaran exhibits several molluscan traits, which justifies its position as a molluscan stem‐group member, rather than as a more basal Lophotrochozoan. The interrelationships among the conchiferan molluscs are still a matter of contention and require further palaeontological and molecular phylogenetic scrutiny.     

Endogenous serotonin release from the dopamine-deficient striatum of the weaver mutant mouse

In addition to an altered dopaminergic input, the striatum of the weaver mutant mouse (wv/wv) has increased serotonin tissue content and uptake compared to the wild-type mouse (+/+). To gain information regarding the functional status of serotonergic inputs to thewv/wv striatum, endogenous serotonin release fromwv/wv and +/+ striatum was measured under basal conditions as well as in the presence of fenfluramine or elevated concentrations of potassium (K⁺). Fractional basal release of serotonin from the +/+ striatum was significantly greater than that from thewv/wv striatum. In the presence of K⁺, evoked release (stimulated release minus basal release) was greater from the +/+ striatum than from thewv/wv striatum. In the presence of fenfluramine, evoked serotonin release was greater from thewv/wv striatum compared to the +/+ striatum. These data are consistent with the involvement of an additional transmitter(s) in modulating serotonin release to a greater extent in thewv/wv than the +/+ striatum. The data on fenfluramine-stimulated serotonin release suggest that the additional serotonin content found in thewv/wv striatum is in a releasable pool but that striatal serotonin release might be attenuated more inwv/wv than in +/+ mice.