Transcriptome analysis of the central nervous system of the mollusc Lymnaea stagnalis.

BACKGROUND: The freshwater snail Lymnaea stagnalis (L. stagnalis) has served as a successful model for studies in the field of Neuroscience. However, a serious drawback in the molecular analysis of the nervous system of L. stagnalis has been the lack of large-scale genomic or neuronal transcriptome information, thereby limiting the use of this unique model. RESULTS: In this study, we report 7,712 distinct EST sequences (median length: 847 nucleotides) of a normalized L. stagnalis central nervous system (CNS) cDNA library, resulting in the largest collection of L. stagnalis neuronal transcriptome data currently available. Approximately 42% of the cDNAs can be translated into more than 100 consecutive amino acids, indicating the high quality of the library. The annotated sequences contribute 12% of the predicted transcriptome size of 20,000. Surprisingly, approximately 37% of the L. stagnalis sequences only have a tBLASTx hit in the EST library of another snail species Aplysia californica (A. californica) even using a low stringency e-value cutoff at 0.01. Using the same cutoff, approximately 67% of the cDNAs have a BLAST hit in the NCBI non-redundant protein and nucleotide sequence databases (nr and nt), suggesting that one third of the sequences may be unique to L. stagnalis. Finally, using the same cutoff (0.01), more than half of the cDNA sequences (54%) do not have a hit in nematode, fruitfly or human genome data, suggesting that the L. stagnalis transcriptome is significantly different from these species as well. The cDNA sequences are enriched in the following gene ontology functional categories: protein binding, hydrolase, transferase, and catalytic enzymes. CONCLUSION: This study provides novel molecular insights into the transcriptome of an important molluscan model organism. Our findings will contribute to functional analyses in neurobiology, and comparative evolutionary biology. The L. stagnalis CNS EST database is available at http://www.Lymnaea.org/.

An action potential-induced and ryanodine sensitive calcium transient dynamically regulates transmitter release at synapses between Lymnaea neurons.

The notion that calcium released through ryanodine receptors effects presynaptic neurotransmitter release is gaining acceptance with the observation that this calcium does indeed contribute to both action potential-evoked and spontaneous transmitter release in a variety of preparations. However, the dynamics of this calcium release and its impact on transmitter release has not yet been fully elucidated. Moreover, in contrast to vertebrate synapses, much less is known about the involvement of ryanodine receptors in the regulation of transmitter release at invertebrate synapses. In this study, we reconstructed specific synapses between individually identifiable preand postsynaptic neurons from Lymnaea to demonstrate that although ryanodine reduces the amplitude of the action potential-induced calcium transient, it does not however, alter the resting calcium level. These data suggest that action potential-induced calcium release through ryanodine receptors is fast and highly dynamic and in turn regulates transmitter release at reconstructed synapses between Lymnaea neurons. This study thus provides direct evidence that a dynamic ryanodine receptor-mediated calcium transient occurs with the presynaptic action potential.

Activity-induced large amplitude postsynaptic mPSPs at soma-soma synapses between Lymnaea neurons.

Spontaneous transmitter release has been observed at various synapses that permit analysis at a sufficient resolution as a miniature postsynaptic potential (mPSP). However, the precise mechanisms that regulate spontaneous transmitter release have not yet been fully defined. Activity and ligand-mediated modulation of large amplitude, spontaneous events significantly enhances postsynaptic excitation in the absence of action potential activity suggesting a more complicated role for this mode of transmitter release, and thus warrants further analysis. Here, we used Lymnaea soma-soma synaptic connections to demonstrate that a transient increase in both the frequency and amplitude of spontaneous events (mPSPs) occurs following a short burst of action potentials in the presynaptic cell. These events were of presynaptic origin and the increase in mPSP amplitude could also be achieved with a stimulatory concentration of ryanodine. Ryanodine also occluded the activity-induced increase in mPSP amplitude implicating calcium release from these channels in the production of large amplitude spontaneous transmitter release events. This suggests that presynaptic activity triggers ryanodine receptor-mediated large amplitude minis, indicating that although these events are action potential-independent, they are nevertheless responsive to the prior activity of the synapse.

In vitro reconstruction of the respiratory central pattern generator of the mollusk Lymnaea.

Most rhythmic behaviors such as respiration, locomotion, and feeding are under the control of networks of neurons in the central nervous system known as central pattern generators (CPGs). The respiratory rhythm of the pond snail Lymnaea stagnalis is a relatively simple, CPG-based behavior for which the underlying neural elements have been identified. A three-neuron network capable of generating the respiratory rhythm of this air-breathing mollusk has been reconstructed in culture. The intrinsic and network properties of this neural ensemble have been studied, and the mechanism of postinhibitory rebound excitation was found to be important for the rhythm generation. This in vitro model system enables a better understanding of the neural basis of rhythm generation.

CRNF, a molluscan neurotrophic factor that interacts with the p75 neurotrophin receptor.

A 13.1-kilodalton protein, cysteine-rich neurotrophic factor (CRNF), was purified from the mollusk Lymnaea stagnalis by use of a binding assay on the p75 neurotrophin receptor. CRNF bound to p75 with nanomolar affinity but was not similar in sequence to neurotrophins or any other known gene product. CRNF messenger RNA expression was highest in adult foot subepithelial cells; in the central nervous system, expression was regulated by lesion. The factor evoked neurite outgrowth and modulated calcium currents in pedal motor neurons. Thus, CRNF may be involved in target-derived trophic support for motor neurons and could represent the prototype of another family of p75 ligands.

Transplantation and functional integration of an identified respiratory interneuron in Lymnaea stagnalis.

The possibility that damaged neural circuitries can be repaired through grafting has raised questions regarding the cellular mechanisms required for functional integration of transplanted neurons. Invertebrate models offer the potential to examine such mechanisms at the resolution of single identified neurons within well-characterized neural networks. Here it is reported that a specific deficit in the respiratory behavior of a pulmonate mollusc, caused by the ablation of a solitary interneuron, can be restored by grafting an identical donor interneuron. The transplanted interneuron not only survives and extends neurites within the host nervous system, but under specific conditions forms synapses with appropriate target neurons and is physiologically integrated into the host's circuitry, thereby restoring normal behavior.

Serotonin modulates transmitter release at central Lymnaea synapses through a G-protein-coupled and cAMP-mediated pathway.

Neuromodulation is central to all nervous system function, although the precise mechanisms by which neurotransmitters affect synaptic efficacy between central neurons remain to be fully elucidated. In this study, we examined the neuromodulatory action of serotonin [5-hydroxytryptamine (5-HT)] at central synapses between identified neurons from the pond snail Lymnaea stagnalis. Using whole-cell voltage-clamp and sharp electrode recording, we show that 5-HT strongly depresses synaptic strength between cultured, cholinergic neuron visceral dorsal 4 (VD4 - presynaptic) and its serotonergic target left pedal dorsal 1 (LPeD1 - postsynaptic). This inhibition was accompanied by a reduction in synaptic depression, but had no effect on postsynaptic input resistance, indicating a presynaptic origin. In addition, serotonin inhibited the presynaptic calcium current (I(Ca)) on a similar time course as the change in synaptic transmission. Introduction of a non-condensable GDP analog, GDP-beta-S, through the presynaptic pipette inhibited the serotonin-mediated effect on I(Ca.) Similar results were obtained with a membrane-impermeable inactive cAMP analog, 8OH-cAMP. Furthermore, stimulation of the serotonergic postsynaptic cell also inhibited presynaptic currents, indicating the presence of a negative feedback loop between LPeD1 and VD4. Taken together, this study provides direct evidence for a negative feedback mechanism, whereby the activity of a presynaptic respiratory central pattern-generating neuron is regulated by its postsynaptic target cell. We demonstrate that either serotonin or LPeD1 activity-induced depression of presynaptic transmitter release from VD4 involves voltage-gated calcium channels and is mediated through a G-protein-coupled and cAMP-mediated system.

Reconstruction of neuronal networks in culture.

Since the 1960s, the large neurones of some invertebrates have been exploited in attempts to define the neural circuits that underlie simple behaviours. Even in the relatively 'simple' nervous systems of these animals, it is often difficult to study individual synaptic connections in detail and to rule out involvement of unidentified neurones. These limitations have been overcome by reconstruction of partial circuits of identified neurones in cell culture. This approach has provided opportunities to examine the function of small neuronal circuits in a manner that is unapproachable in the intact nervous system.

Transmitter-receptor interactions between growth cones of identified Lymnaea neurons determine target cell selection in vitro.

In addition to their involvement in transsynaptic communication in the adult nervous system, neurotransmitters also participate in many developmental events, such as neurite initiation and outgrowth. Although growth cones can release transmitters and are themselves sensitive to exogenously applied neurotransmitters, a direct causal relationship between the release of transmitter from one growth cone and its effect on another has not yet been demonstrated. In this study, we provide evidence that dopamine release from the growth cones of an identified Lymnaea neuron, right pedal dorsal 1 (RPeD1), differentially regulates the growth cone behavior of its in vivo target and nontarget neurons in vitro. In coculture, RPeD1 growth cones enhanced the rate of growth cone advance from target cells and synaptic connections developed immediately after contact. In contrast, RPeD1 growth cones not only inhibited the rate of growth cone advance from nontarget cells but they also induced growth cone collapse. Using a "sniffer cell" approach, we demonstrated that both RPeD1 growth cones and somata released dopamine, which can be detected at a distance of several hundred micrometers. RPeD1 somata were used to demonstrate that spontaneous release of dopamine also acted as a chemoattractant for target growth cones but as a chemorepellent for nontarget growth cones. These effects were mimicked by exogenous dopamine application, and both RPeD1 growth cone and soma-induced effects were also blocked in the presence of dopamine receptor antagonists. This study emphasizes the importance of transmitter-receptor interactions between growth cones in target cell selection.

Synapse formation between central neurons requires postsynaptic expression of the MEN1 tumor suppressor gene.

Synapse formation is a crucial step in the development of neuronal circuits and requires precise coordination of presynaptic and postsynaptic activities. However, molecular mechanisms that control the formation of functionally mature synaptic contacts, in particular between central neurons, remain poorly understood. To identify genes that are involved in the formation of central synapses, we made use of molluscan neurons that in culture form synaptic contacts between their somata (soma-soma synapses) in the absence of neurite outgrowth. Using single-cell mRNA differential display, we have identified a molluscan homolog of the multiple endocrine neoplasia type 1 (MEN1) tumor suppressor gene encoding the transcription factor menin as a gene that is upregulated during synapse formation. In vitro antisense knock-down of MEN1 mRNA blocks the formation of mature synapses between different types of identified central neurons. Moreover, immunocytochemistry and cell-specific knock-down of MEN1 mRNA show that postsynaptic but not presynaptic expression is required for synapses to form. Together, our data demonstrate that menin is a synaptogenic factor that is critically involved in a general postsynaptic mechanism of synapse formation between central neurons.

Functional implications of neurotransmitter expression during axonal regeneration: serotonin, but not peptides, auto-regulate axon growth of an identified central neuron.

We studied the regenerative properties of one of two electrically coupled molluscan neurons, the serotonergic cerebral giant cells (CGCs) of Lymnaea stagnalis, after axotomy. The CGCs play a crucial role in feeding behavior, and when both cells are disconnected from their target neurons, animals no longer feed. When one CGC was permanently disconnected from its targets and the other was reversibly damaged by a nerve crush, the latter one regenerated over a period of 2 weeks to reform functional synapses with specific target neurons. At the same time, recovery of the feeding behavior was observed. After the crush, neuropeptide gene expression in the CGC was downregulated to approximately 50%. Serotonin synthesis, on the other hand, remained unaffected, suggesting that serotonin might have an active role in regeneration. In primary neuron culture, CGCs failed to extend neurites in the presence of serotonin; in cells that extended neurites in the absence of serotonin, focally applied serotonin, but not neuropeptides, induced growth cone collapse. Using serotonin-sensitive sniffer cells, we show that CGC neurites and growth cones release serotonin in culture. Finally, both the spontaneous and stimulation-induced release of serotonin from CGCs in culture resulted in growth cone collapse responses that could be blocked by the serotonin receptor antagonist methysergide. Our data suggest that auto-released serotonin is inhibitory to CGC neurite outgrowth in vitro. During regeneration in vivo, serotonin release might fine-tune axon guidance and branching by inducing local collapse responses in extending neurites.

Excitatory synaptogenesis between identified Lymnaea neurons requires extrinsic trophic factors and is mediated by receptor tyrosine kinases.

Neurotrophic factors have well established roles in neuronal development and adult synaptic plasticity, but their precise role in synapse formation has yet to be determined. This paper provides the first direct evidence that neurotrophic factors in brain conditioned medium (CM) differentially regulate excitatory and inhibitory synapse formation. Somata of identified presynaptic and postsynaptic neurons were isolated from the CNS of Lymnaea and were cultured in a soma-soma configuration in the presence (CM) or absence [defined medium (DM)] of trophic factors. In DM, excitatory synapses did not form. When they were paired in CM or in DM containing Lymnaea epidermal growth factor (EGF); however, all presynaptic neurons reestablished their specific excitatory synapses, which had electrical properties similar to those seen in vivo. CM-induced formation of excitatory synapses required transcription and de novo protein synthesis, as indicated by the observations that synapse formation was blocked by the protein synthesis inhibitor anisomycin and the protein transcription blocker actinomycin D; the CM factor was inactivated by boiling. They were also blocked by receptor tyrosine kinase inhibitors (lavendustin A, genistein, K252a, and KT5926) but not by inactive analogs (genistin and lavendustin B), suggesting that the effect was mediated by receptor tyrosine kinases. These results, together with our previously published data, demonstrate that trophic factors are required for excitatory, but not inhibitory, synapse formation and extends the role of EGF from cell proliferation, neurite outgrowth, and survival to excitatory synapse formation.

De novo protein synthesis in isolated axons of identified neurons.

Neurons are highly polarized cells that contain a wealth of cytoplasmic and membrane proteins required for neurotransmission, synapse formation and various forms of neuronal plasticity. Typically, these proteins are differentially distributed over somatic, dendritic and axonal compartments. Until recently, it was believed that all proteins destined for various neuronal sites were synthesized exclusively in the somata and were subsequently targeted to appropriate extrasomal compartments. The discovery of various messenger RNA molecules in both dendrites and axons is suggestive of de novo protein synthesis in extrasomatic regions. The latter process has been demonstrated in few neuronal svrstems, but direct proof for the axonal transcription of a specific protein from a given messenger RNA is still lacking. This lack of fundamental knowledge in the field of cellular and molecular neurobiology is due primarily to both anatomical and experimental difficulties encountered in most animal preparations studied thus far. In this study we developed a neuronal experimental system comprising of individually identified neurons and their isolated axons from the mollusc Lymnaea stagnalis. We injected a foreign messenger RNA encoding a peptide precursor into the isolated axons of cultured neurons; and utilizing cellular, molecular and immunocytochemical techniques, we provide direct evidence for specific protein synthesis in isolated axons. The Lymnaea model provides us with an opportunity to examine the role and specificity of de novo protein synthesis in the extrasomal regions.

Glutamate as a putative neurotransmitter in the mollusc, Lymnaea stagnalis.

Bath-applied glutamate (10-1000 microM) produced excitatory and inhibitory responses on numerous identified neurons of the mollusc Lymnaea stagnalis. Using both in situ and in vitro preparations, glutamate or glutamate agonists produced a depolarization in identified neurons right pedal dorsal 1 and right pedal dorsal 2 and 3. However, attempts to block glutamate-evoked responses with glutamate antagonists were unsuccessful. We examined a potential glutamatergic neuron, visceral dorsal 4. Exogenous application of the peptides (GDPFLRFamide and SDPFLRFamide) could mimic the inhibitory, but not the excitatory effects of visceral dorsal 4 on its postsynaptic cells, implying the presence of a second transmitter. We tested the possibility that glutamate is this second neurotransmitter by using excitatory synapses between visceral dorsal 4 and postsynaptic cells right pedal dorsal 2 and 3, right pedal dorsal 1, visceral F group and right parietal B group neurons. Of all the putative neurotransmitters tested, only glutamate had consistent excitatory effects on these postsynaptic cells. Also, the amplitude of the right pedal dorsal 2 and 3 excitatory postsynaptic potentials was reduced in the presence of N-methyl-D-aspartate and other glutamate agonists, suggesting desensitization of the endogenous transmitter receptor. In conclusion, some identified Lymnaea neurons respond to glutamate via a receptor with novel pharmacological properties. Furthermore, a Lymnaea interneuron may employ glutamate as a transmitter at excitatory synapses.

Specific in vitro synaptogenesis between identified Lymnaea and Helisoma neurons.

We tested the ability of identified neurons from two different families of pulmonate molluscs to form specific connections in vitro. The presynaptic neuron chosen for this study was the giant dopamine cell of Lymnaea stagnalis and Helisoma trivolvis which is known to synapse upon specific visceral and parietal ganglion neurons in both species. Here we show that the giant dopamine cells can reform specific connections in vitro on follower neurons from both species. Thus the mechanisms that determine synapse specificity are conserved between two different families of molluscs.

Retrograde degeneration of neurite membrane structural integrity of nerve growth cones following in vitro exposure to mercury.

Inhalation of mercury vapor (Hg0) inhibits binding of GTP to rat brain tubulin, thereby inhibiting tubulin polymerization into microtubules. A similar molecular lesion has also been observed in 80% of brains from patients with Alzheimer disease (AD) compared to age-matched controls. However the precise site and mode of action of Hg ions remain illusive. Therefore, the present study examined whether Hg ions could affect membrane dynamics of neurite growth cone morphology and behavior. Since tubulin is a highly conserved cytoskeletal protein in both vertebrates and invertebrates, we hypothesized that growth cones from animal species could be highly susceptible to Hg ions. To test this possibility, the identified, large Pedal A (PeA) neurons from the central ring ganglia of the snail Lymnoea stagnalis were cultured for 48 h in 2 ml brain conditioned medium (CM). Following neurite outgrowth, metal chloride solution (2 microl) of Hg, Al, Pb, Cd, or Mn (10(-7) M) was pressure applied directly onto individual growth cones. Time-lapse images with inverted microscopy were acquired prior to, during, and after the metal ion exposure. We demonstrate that Hg ions markedly disrupted membrane structure and linear growth rates of imaged neurites in 77% of all nerve growth cones. When growth cones were stained with antibodies specific for both tubulin and actin, it was the tubulin/microtubule structure that disintegrated following Hg exposure. Moreover, some denuded neurites were also observed to form neurofibrillary aggregates. In contrast, growth cone exposure to other metal ions did not effect growth cone morphology, nor was their motility rate compromised. To determine the growth suppressive effects of Hg ions on neuronal sprouting, cells were cultured either in the presence or absence of Hg ions. We found that in the presence of Hg ions, neuronal somata failed to sprout, whereas other metalic ions did not effect growth patterns of cultured PeA cells. We conclude that this visual evidence and previous biochemical data strongly implicate Hg as a potential etiological factor in neurodegeneration.

Nitric oxide synthase-immunoreactive cells in the CNS and periphery of Lymnaea.

The presence and distribution of nitric oxide synthase (NOS) in the CNS and peripheral organs (buccal muscles, oesophagus, salivary glands, foot, mantle and pneumostome) of the pulmonate mollusc, Lymnaea stagnalis were studied using an antiserum developed against rat cerebellar NOS. NOS-immunopositive neurones in Lymnaea were localized predominantly in the buccal ganglia as well as in distinct areas of the cerebral and suboesophageal ganglia. NOS-immunoreactive terminals were also found on the somata of some central neurones. In the periphery, NOS-immunostaining was detected only in a few neurones in the pneumostome area and in the osphradial ganglion. In addition, approximately 100 NOS-immunopositive cells have been found in the salivary glands. Our data supports other recent reports indicating that NO may be a signal molecule in the CNS of molluscs.

A technique for the primary dissociation of neurons from restricted regions of the vertebrate CNS.

Acute isolation of vertebrate neurons has been used extensively to characterize membrane properties in the absence of circuit connections or extensive dendritic arborizations. We describe a technique that allows cells to be dissociated from anatomically defined regions of a tissue slice at a resolution beyond that attainable by micro-dissection. Dissociation is performed by using a fire-polished electrode with a tip diameter of 40-100 microns connected by tubing to a micrometer syringe that allows graded levels of positive or negative pressure to be applied at the electrode tip. The electrode tip is placed under microscopic observation upon a cell group within an enzymatically treated slice and negative pressure is applied to dissociate cells into the electrode shaft. Positive pressure is used to eject the cells onto the surface of poly-L-lysine-coated glass coverslips. We have used this technique to dissociate and culture cells from specific laminae of separate sensory maps in a medullary nucleus of adult weakly electric fish. Isolated cells were viable, could be identified by morphological criteria, and exhibited process extension within 2 h of plating. This technique greatly increases the probability of isolating morphologically identifiable vertebrate neurons for electrophysiological analysis or for the reconstruction of neural circuits in vitro.

A neuronal network from the mollusc Lymnaea stagnalis.

The morphology, electrophysiology, and synaptic inputs of a ventrally located neuronal network from the CNS of the pond snail Lymnaea stagnalis was investigated. Three large, previously identified neurons [55] known as right parietal ventral one, two, and three (RPV1,2,&3) were found to be electrically coupled to one another. Coupling between either RPV1&2 or RPV1&3 was weak while coupling between RPV2&3 was strong. Consistent bursting activity was observed in neuron RPV1 while neurons RPV2&3 were either silent or fired tonically. When isolated in vitro, similar patterns of activity could be elicited in neurons RPV1-3. Lucifer yellow staining revealed that these cells send axons through nerves innervating musculature involved in locomotion, whole-body withdrawal, and cardio-respiratory function. Neurons RPV1-3 were found to be inhibited by an identified interneuron, visceral dorsal four, known to be directly involved in cardio-respiratory behavior [43]. Furthermore, neurons RPV1-3 were also inhibited by a wide-acting synaptic input, known as Input three [9], which is associated with respiratory pattern generation [43]. An interneuron, identified as right pedal dorsal eleven (RPeD11), which coordinates locomotory and withdrawal behavior [44], was found to excite neuron RPV1. When neurons RPeD11 and RPV1 were isolated in vitro and allowed to extend neurites, they formed a synaptic connection similar to that observed in the isolated brain. In vitro work on these neurons may make them an attractive model to study synapse formation and bursting activity.

Halothane affects both inhibitory and excitatory synaptic transmission at a single identified molluscan synapse, in vivo and in vitro.

In the isolated CNS of Lymnaea, a peptidergic neuron termed VD4 makes monosynaptic connections with identified pedal A cluster neurons. In this study, the pedal A (PeA) neurons were further divided into two subgroups depending upon whether they received an inhibitory or excitatory input from VD4. PeA cells inhibited by VD4 were designated PeA(I), whereas those excited by VD4 were termed PeA(E). Both inhibitory and excitatory effects of VD4 stimulation on the PeA(I) and PeA(E) cells, respectively, were mimicked by exogenous FMRFamide in culture (in vitro), implicating this or a related peptide as the transmitter utilized at the VD4-to-PeA synapses. We tested the ability of the general anesthetic, halothane, to affect either the inhibitory or the excitatory peptidergic synapses between VD4 and the PeA neurons, both in the isolated CNS (in vivo) and at the in vitro reconstructed synapses. In the presence of 1% halothane, the excitatory synaptic potential between VD4 and the PeA(E) cells was either depressed or completely abolished, whereas the inhibitory synaptic potential between VD4 and the PeA(I) cells was unaffected in the presence of 1% halothane. The inhibitory potential between VD4 and the PeA(I) cells was, however, blocked in 2% halothane. In order to determine halothane' 5 site of action, exogenous FMRFamide was applied to both PeA(E) and PeA(I) cells in the presence of 1 or 2% halothane. In 1% halothane, the excitatory responses produced by FMRFamide were substantially reduced or abolished, whereas the inhibitory responses to FMRFamide were maintained and enhanced in duration in 1% halothane. In 2% halothane, the inhibitory responses to exogenous FMRFamide remained unchanged. It, therefore, appears that halothane exerts effects at both the pre- and postsynaptic level of the synapse, although presynaptic transmitter release is probably not substantially affected until a concentration of 2% halothane is reached. Our data provide the first evidence that clinically relevant concentrations of halothane (1-2%) affect both excitatory and inhibitory peptidergic synaptic transmission between identified neurons in the nervous system. Furthermore, excitatory transmission is abolished at lower anesthetic concentrations than inhibitory transmission.