Target cell contact suppresses neurite outgrowth from soma-soma paired Lymnaea neurons

Neurite extension from developing and/or regenerating neurons is terminated on contact with their specific synaptic partner cells. However, a direct relationship between the effects of target cell contact on neurite outgrowth suppression and synapse formation has not yet been demonstrated. To determine whether physical/synaptic contacts affect neurite extension from cultured cells, we utilized soma-soma synapses between the identified Lymnaea neurons. A presynaptic cell (right pedal dorsal 1, RPeD1) was paired either with its postsynaptic partner cells (visceral dorsal 4, VD4, and Visceral dorsal 2, VD2) or with a non-target cell (visceral dorsal 1, VD1), and the interactions between their neurite outgrowth patterns and synapse formation were examined. Specifically, when cultured in brain conditioned medium (CM, contains growth-promoting factors), RPeD1, VD4, and VD2 exhibited robust neurite outgrowth within 12-24 h of their isolation. Synapses, similar to those seen in vivo, developed between the neurites of these cells. RPeD1 did not, however, synapse with its non-target cell VD1, despite extensive neuritic overlap between the cells. When placed in a soma-soma configuration (somata juxtaposed against each other), appropriate synapses developed between the somata of RPeD1 and VD4 (inhibitory) and between RPeD1 and VD2 (excitatory). Interestingly, pairing RPeD1 with either of its synaptic partner (VD4 or VD2) resulted in a complete suppression of neurite outgrowth from both pre- and postsynaptic neurons, even though the cells were cultured in CM. A single cell in the same dish, however, extended elaborate neurites. Similarly, a postsynaptic cell (VD4) contact suppressed the rate of neurite extension from a previously sprouted RPeD1. This suppression of the presynaptic growth cone motility was also target cell contact specific. The neurite suppression from soma-soma paired cells was transient, and neuronal sprouting began after a delay of 48-72 h. In contrast, when paired with VD1, both RPeD1 and this non-target cell exhibited robust neurite outgrowth. We demonstrate that this neurite suppression from soma-soma paired cells was target cell contact/synapse specific and Ca(2+) dependent. Specifically, soma-soma pairing in CM containing either lower external Ca(2+) concentration (50% of its control level) or Cd(2+) resulted in robust neurite outgrowth from both cells; however, the incidence of synapse formation between the paired cells was significantly reduced. Taken together, our data show that contact (physical and/or synaptic) between synaptic partners strongly influence neurite outgrowth patterns of both pre- and postsynaptic neurons in a time-dependent and cell-specific manner. Moreover, our data also suggest that neurite outgrowth and synapse formation are differentially regulated by external Ca(2+) concentration.     

Target cell contact suppresses neurite outgrowth from soma–soma paired Lymnaea neurons

Neurite extension from developing and/or regenerating neurons is terminated on contact with their specific synaptic partner cells. However, a direct relationship between the effects of target cell contact on neurite outgrowth suppression and synapse formation has not yet been demonstrated. To determine whether physical/synaptic contacts affect neurite extension from cultured cells, we utilized soma–soma synapses between the identified Lymnaea neurons. A presynaptic cell (right pedal dorsal 1, RPeD1) was paired either with its postsynaptic partner cells (visceral dorsal 4, VD4, and Visceral dorsal 2, VD2) or with a non‐target cell (visceral dorsal 1, VD1), and the interactions between their neurite outgrowth patterns and synapse formation were examined. Specifically, when cultured in brain conditioned medium (CM, contains growth‐promoting factors), RPeD1, VD4, and VD2 exhibited robust neurite outgrowth within 12–24 h of their isolation. Synapses, similar to those seen in vivo, developed between the neurites of these cells. RPeD1 did not, however, synapse with its non–target cell VD1, despite extensive neuritic overlap between the cells. When placed in a soma–soma configuration (somata juxtaposed against each other), appropriate synapses developed between the somata of RPeD1 and VD4 (inhibitory) and between RPeD1 and VD2 (excitatory). Interestingly, pairing RPeD1 with either of its synaptic partner (VD4 or VD2) resulted in a complete suppression of neurite outgrowth from both pre‐ and postsynaptic neurons, even though the cells were cultured in CM. A single cell in the same dish, however, extended elaborate neurites. Similarly, a postsynaptic cell (VD4) contact suppressed the rate of neurite extension from a previously sprouted RPeD1. This suppression of the presynaptic growth cone motility was also target cell contact specific. The neurite suppression from soma–soma paired cells was transient, and neuronal sprouting began after a delay of 48–72 h. In contrast, when paired with VD1, both RPeD1 and this non‐target cell exhibited robust neurite outgrowth. We demonstrate that this neurite suppression from soma–soma paired cells was target cell contact/synapse specific and Ca²⁺ dependent. Specifically, soma–soma pairing in CM containing either lower external Ca²⁺ concentration (50% of its control level) or Cd²⁺ resulted in robust neurite outgrowth from both cells; however, the incidence of synapse formation between the paired cells was significantly reduced. Taken together, our data show that contact (physical and/or synaptic) between synaptic partners strongly influence neurite outgrowth patterns of both pre‐ and postsynaptic neurons in a time‐dependent and cell‐specific manner. Moreover, our data also suggest that neurite outgrowth and synapse formation are differentially regulated by external Ca²⁺ concentration. © 2000 John Wiley & Sons, Inc. J Neurobiol 42: 357–369, 2000     

Stability and variability of synapses in the adult molluskan CNS

Synaptic transmission was examined between identified neurons in the central nervous system (CNS) of the freshwater mollusk, Lymnaea stagnalis. Four identified neurons were used: Right Pedal Dorsal one (RPeD1; a dopaminergic respiratory interneuron), Visceral Dorsal two and three (VD2/3), and Visceral Dorsal four (VD4; a cardiorespiratory interneuron). Neuron RPeD1 synapses onto both VD2/3 and VD4, while VD4 makes a reciprocal synapse onto RPeD1. When compared from animal to animal, the connections were variable in sign. Previously, we demonstrated that, in a given animal, the RPeD1 --> VD4 synapse could be either inhibitory, biphasic, or undetectable. The present study now expands this concept of variability by showing that the RPeD1 --> VD2/3 synapse was either excitatory or undetectable from animal to animal, while the synapse from VD4 to RPeD1 was observed as inhibitory, biphasic, depolarizing, excitatory, or undetectable. Next, we used 1-day organ culture to determine if the variability observed between animals is a product of ongoing change to the sign of these identified synapses and whether or not the extent of change could be influenced by the culture conditions. Changes to the sign of transmission occurred within minutes and, more commonly, after 24-h organ culture. All three synapses were investigated before and after 1-day organ culture, in either defined medium (DM) or brain-conditioned medium (CM). Regardless of culture conditions, the RPeD1 --> VD2/3 synapse showed no change of sign, i.e., it was relatively stable. However, the synapses between RPeD1 and VD4 did change sign, and when cultured in CM, the VD4 --> RPeD1 synapse changed significantly more than in DM. These data indicate that variability of some synapses reflects changes at these synapses. This is the first report that specific synapses in an adult CNS can change sign, and that the sign of transmission can be modulated by environmental conditions.     

Arterial cells and CNS sheath cells from Aplysia californica produce factors that enhance neurite outgrowth in co-cultured neurons

Substrate-bound and soluble factors regulate neurite outgrowth and synapse formation during development, regeneration, and learning and memory. We report that sheath cells from CNS connectives and arterial cells from the anterior aorta of the sea slug, Aplysia californica, enhance neurite outgrowth from co-cultured Aplysia neurons. Sheath and arterial cell cultures contain several cell types, including fibrocytes, myocytes, and amoebocytes. When compared to controls (neurons with defined growth medium alone), the percentage of neurons with growth and the average neurite lengths are significantly enhanced by sheath and arterial cells at 48 h after plating of the neurons; these parameters are comparable to those of neurons cultured in medium containing hemolymph. Our results indicate that sheath cells produce substrate-bound factor(s) and arterial cells produce diffusible factor(s) that promote growth. These growth factors likely promote neuron survival and neurite outgrowth during neural plasticity exhibited in the adult CNS. Electronic Publication     

Aplysia hemolymph promotes neurite outgrowth and synaptogenesis of identifiedHelix neurons in cell culture

Hemolymph of adultAplysia californica significantly affects neurite outgrowth of identified neurons of the land snailHelix pomatia. The metacerebral giant cell (MGC) and the motoneuron C3 from the cerebral ganglion and the neuron B2 from the buccal ganglion ofH. pomatia were isolated by enzymatic and mechanical dissociation and plated onto poly-l-lysine-coated dishes either containing culture medium conditioned byHelix ganglia, or pre-treated withAplysia hemolymph. To determine the extent of neuronal growth we measured the neurite elongation and the neuritic field of cultured neurons at different time points.Aplysia hemolymph enhances the extent and rate of linear outgrowth and the branching domain ofHelix neurons. With the hemolymph treatment the MGC neuron more consistently forms specific chemical synapses with its follower cell B2, and these connections are more effective than those established in the presence of the conditioned medium.     

Dopamine-mediated calcium channel regulation in synaptic suppression in L. stagnalis interneurons

D2 dopamine receptor-mediated suppression of synaptic transmission from interneurons plays a key role in neurobiological functions across species, ranging from respiration to memory formation. In this study, we investigated the mechanisms of D2 receptor-dependent suppression using soma-soma synapse between respiratory interneuron VD4 and LPeD1 in the mollusk Lymnaea stagnalis (L. stagnalis). We studied the effects of dopamine on voltage-dependent Ca²⁺ current and synaptic vesicle release from the VD4. We report that dopamine inhibits voltage-dependent Ca²⁺ current in the VD4 by both voltage-dependent and -independent mechanisms. Dopamine also suppresses synaptic vesicle release downstream of activity-dependent Ca²⁺ influx. Our study demonstrated that dopamine acts through D2 receptors to inhibit interneuron synaptic transmission through both voltage-dependent Ca²⁺ channel-dependent and -independent pathways. Taken together, these findings expand our understanding of dopamine function and fundamental mechanisms that shape the dynamics of neural circuit.     

Characterization of a novel molluskan tyrosine kinase receptor that inhibits neurite regeneration

Receptor tyrosine kinases play many important roles in neuronal signaling including regulating neurite outgrowth. We have identified a novel receptor tyrosine kinase, neurite outgrowth regulating kinase (nork) from Aplysia californica. A fragment of this kinase was also identified in another mollusk, Lymnaea. The kinase domain is equally homologous to the Ret (rearranged during transformation) and fibroblast growth factor receptor families, but the extracellular domain is entirely novel, suggesting that it binds a nonconserved ligand. Overexpression of neurite outgrowth regulating kinase, but not a kinase dead form, causes a reduction in neurite outgrowth of Aplysia sensory neurons. Thus, we have identified a novel receptor tyrosine kinase implicated in regulating neurite outgrowth.     

On the status of the study of invertebrate neurons in tissue culture--phyla Mollusca and Annelida

The utilization of tissue culture in neurobiological studies is discussed for all phyla phylogenetically preceding Phylum Arthropoda. Only two phyla, Mollusca and Annelida, are represented in such studies. The members of Phylum Mollusca which have been so investigated are Aplysia, Helisoma and Lymnaea. The mollusc Aplysia has been used to investigate several processes, including neurosecretion, synaptic transmission and synaptogenesis. Helisoma was employed to study factors regulating neurite growth and the specificity of synapse formation; mechanisms of neurite growth were investigated in the snail Lymnaea. The only member of Phylum Annelida involved in appropriate studies has been the leech Hirudo. This organism was used to investigate axonal regeneration and synaptic mechanisms.     

Synapse formation and function: Insights from identified leech neurons in culture

Identified leech neurons in culture are providing novel insights to the signals underlying synapse formation and function. Identified neurons from the central nervous system of the leech can be removed individually and plated in culture, where they retain their characteristic physiological properties, grow neurites, and form specific synapses that are directly accessible by a variety of approaches. Synapses between cultured neurons can be chemical or electrical (either rectifying or not) or may not form, depending on the neuronal identities. Furthermore, the characteristics of these synapses depend on the regions of the cells that come into contact. The formation and physiology of synapses between the Retzius cell and its partners have been well characterized. Retzius cells form purely chemical, inhibitory synapses with pressuresensitive (P) cells where serotonin (5-HT) is the transmitter. Retzius cells synthesize 5-HT, which is stored in vesicles that recycle after 5-HT is secreted on stimulation. The release of 5-HT is quantal, calcium-dependent, and shows activity-dependent facilitation and depression. Anterograde and retrograde signals during synapse formation modify calcium currents, responses to 5-HT, and neurite outgrowth. The nature of these synaptogenic signals is being elucidated. For example, contact specifically with Retzius cells induces a localized selection of transmitter responses in postsynaptic P cells. This effect is signaled by tyrosine phosphorylation prior to synapse formation. © 1995 John Wiley & Sons, Inc.     

Localization,physiology, and modulation of a molluskan dopaminergic synapse

We investigated the location, physiology, and modulation of an identified synapse from the central nervous system (CNS) of the mollusk Lymnaea stagnalis. Specifically, the excitatory synapse from interneuron right pedal dorsal one (RPeD1) to neurons visceral dorsal two and three (VD2/3) was examined. The gross and fine morphology of these neurons was determined by staining with Lucifer yellow or sulforhodamine. In preparations where RPeD1 was stained with Lucifer yellow and VD2/3 with sulfo-rhodamine, the axon collaterals occupied similar regions, suggesting that these neurons make physical contact in the CNS. Digital confocal microscopy of these preparations revealed that presynaptic varicosities made apparent contact (synapses) with smooth postsynaptic axon collaterals. The number of putative synapses per preparation was about five to 10. Regarding physiology, the synaptic latency was moderately rapid at 24.1 ± 5.2 ms. Previous work indicated that RPeD1 uses dopamine as a neurotransmitter. The RPeD1 → VD2/3 excitatory postsynaptic potential (EPSP) and the VD2/3 bath-applied dopamine (100-μM) response displayed a similar decrease in input resistance and a similar predicted reversal potential (−31 vs. −26 mV), indicating that the synapse and exogenous dopamine activate the same conductance. Finally, bath-applied serotonin (10 μM) rapidly and reversibly depressed the RPeD1 → VD2/3 synapse but did not affect the VD2/3 bath-applied dopamine (100-μM) response, suggesting a presynaptic locus of action for serotonin. The effect of serotonin was not associated with any changes to the pre- or postsynaptic membrane potential and input resistance, or the presynaptic action potential half-width. The RPeD1 → b3 VD2/3 synapse provides an opportunity to examine the anatomy and physiology of transmission, and is amenable to the study of neuromodulation. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 247–264, 1997     

Neuroligin-1 Overexpression in Newborn Granule Cells In Vivo

Adult-born dentate granule cells integrate into the hippocampal network, extend neurites and form synapses in otherwise mature tissue. Excitatory and inhibitory inputs innervate these new granule cells in a stereotyped, temporally segregated manner, which presents a unique opportunity to study synapse development in the adult brain. To examine the role of neuroligins as synapse-inducing molecules in vivo, we infected dividing neural precursors in adult mice with a retroviral construct that increased neuroligin-1 levels during granule cell differentiation. By 21 days post-mitosis, exogenous neuroligin-1 was expressed at the tips of dendritic spines and increased the number of dendritic spines. Neuroligin-1-overexpressing cells showed a selective increase in functional excitatory synapses and connection multiplicity by single afferent fibers, as well as an increase in the synaptic AMPA/NMDA receptor ratio. In contrast to its synapse-inducing ability in vitro, neuroligin-1 overexpression did not induce precocious synapse formation in adult-born neurons. However, the dendrites of neuroligin-1-overexpressing cells did have more thin protrusions during an early period of dendritic outgrowth, suggesting enhanced filopodium formation or stabilization. Our results indicate that neuroligin-1 expression selectively increases the degree, but not the onset, of excitatory synapse formation in adult-born neurons.     

Synapse formation regulated by protein tyrosine phosphatase receptor T through interaction with cell adhesion molecules and Fyn

The receptor‐type protein tyrosine phosphatases (RPTPs) have been linked to signal transduction, cell adhesion, and neurite extension. PTPRT/RPTPρ is exclusively expressed in the central nervous system and regulates synapse formation by interacting with cell adhesion molecules and Fyn protein tyrosine kinase. Overexpression of PTPRT in cultured neurons increased the number of excitatory and inhibitory synapses by recruiting neuroligins that interact with PTPRT through their ecto‐domains. In contrast, knockdown of PTPRT inhibited synapse formation and withered dendrites. Incubation of cultured neurons with recombinant proteins containing the extracellular region of PTPRT reduced the number of synapses by inhibiting the interaction between ecto‐domains. Synapse formation by PTPRT was inhibited by phosphorylation of tyrosine 912 within the membrane–proximal catalytic domain of PTPRT by Fyn. This tyrosine phosphorylation reduced phosphatase activity of PTPRT and reinforced homophilic interactions of PTPRT, thereby preventing the heterophilic interaction between PTPRT and neuroligins. These results suggest that brain‐specific PTPRT regulates synapse formation through interaction with cell adhesion molecules, and this function and the phosphatase activity are attenuated through tyrosine phosphorylation by the synaptic tyrosine kinase Fyn.     

Synaptic dendritic activity modulates the single synaptic event

Synaptic transmission is the key system for the information transfer and elaboration among neurons. Nevertheless, a synapse is not a standing alone structure but it is a part of a population of synapses inputting the information from several neurons on a specific area of the dendritic tree of a single neuron. This population consists of excitatory and inhibitory synapses the inputs of which drive the postsynaptic membrane potential in the depolarizing (excitatory synapses) or depolarizing (inhibitory synapses) direction modulating in such a way the postsynaptic membrane potential. The postsynaptic response of a single synapse depends on several biophysical factors the most important of which is the value of the membrane potential at which the response occurs. The concurrence in a specific time window of inputs by several synapses located in a specific area of the dendritic tree can, consequently, modulate the membrane potential such to severely influence the single postsynaptic response. The degree of modulation operated by the synaptic population depends on the number of synapses active, on the relative proportion between excitatory and inbibitory synapses belonging to the population and on their specific mean firing frequencies. In the present paper we show results obtained by the simulation of the activity of a single Glutamatergic excitatory synapse under the influence of two different populations composed of the same proportion of excitatory and inhibitory synapses but having two different sizes (total number of synapses). The most relevant conclusion of the present simulations is that the information transferred by the single synapse is not and independent simple transition between a pre- and a postsynaptic neuron but is the result of the cooperation of all the synapses which concurrently try to transfer the information to the postsynaptic neuron in a given time window. This cooperativeness is mainly operated by a simple mechanism of modulation of the postsynaptic membrane potential which influences the amplitude of the different components forming the postsynaptic excitatory response.     

Modulation of growth of Aplysia neurons by an endogenous lectin.

We have purified and characterized a galactose-binding lectin from the gonads of the mollusk Aplysia californica that modulates neurite outgrowth from cultured Aplysia neurons. Agglutination of sheep red blood cells (RBC) by this lectin, termed Aplysia gonad lectin (AGL), is inhibited strongly by galactose and to a lesser extent by fucose. On SDS-PAGE, AGL appears as a single species with a molecular weight of 34 kD under reducing conditions, and 65 kD under nonreducing conditions. This suggests that AGL is a disulfide-linked dimer in its native state. Amino terminal sequence analysis of purified AGL indicates a similarity to another galactose-binding lectin, phytohemagglutinin-E (E-PHA), found in red kidney beans. By using polyclonal antibodies prepared against AGL, we have found that the lectin is present in the gonads and eggs but not in other tissues of adult Aplysia californica. We have examined biological actions of AGL on Aplysia neurons growing in primary cell culture. AGL affects several properties of these neurons. The addition of 100 nM AGL to cultured neurons enhances neurite outgrowth from the cell soma, resulting in a greater number of primary processes. In addition, AGL acts as a neurotrophic agent, increasing neurite viability in vitro. This trophic effect is not seen with concanavalin A (con A), another lectin known to affect several properties of cultured Aplysia neurons. The results are consistent with the suggestion that AGL may play a role in neuronal differentiation and/or maintenance of viability.     

Antiserum Against Neurite Outgrowth Factor in Chick Gizzard Extract and Its Inhibitory Effect on Neuritic Response in Cultured Ciliary Neurons

Abstract: Antiserum against a neurite outgrowth factor (NOF) of gizzard extract that promotes neurite outgrowth from dissociated ciliary ganglionic neurons (CG neurons) of 8-day-old chick embryo was prepared to determine whether or not the antiserum inhibits neurite outgrowth from cultured neurons or explants of chick and murine tissues. When CG neurons were cultured on a polyornithine-coated well exposed to NOF (NOF-bound POR well), marked neurite outgrowth was observed. When NOF-bound POR wells were exposed to antiserum, neurite outgrowth from CG neurons was gradually inhibited with increasing amounts of antiserum, while exposure to preimmune serum did not prevent neurite outgrowth. Antiserum had no effect on neuronal survival during a 48-h incubation. The diluted antiserum, which produced nearly 100% inhibition of the NOF activity, was almost equally active in suppressing the activity of NOFs in conditioned media (CM) of various chick embryo tissues, but showed much less inhibitory effects on NOFs in CM of murine tissues. The appearance of neurites from explants of spinal cord, dorsal root ganglion, or retina of chick embryo was also inhibited by the antiserum. These results indicate that antiserum against NOF from gizzard extract suppressed the activity of NOFs from various sources, and that there are species differences in NOFs, at least between chick and murine.     

Synapse formation and mRNA localization in cultured Aplysia neurons

mRNA localization and regulated translation provide a means of spatially restricting gene expression within neurons during axon guidance and long-term synaptic plasticity. Here we show that synapse formation specifically alters the localization of the mRNA encoding sensorin, a peptide neurotransmitter with neurotrophin-like properties. In isolated Aplysia sensory neurons, which do not form chemical synapses, sensorin mRNA is diffusely distributed throughout distal neurites. Upon contact with a target motor neuron, sensorin mRNA rapidly concentrates at synapses. This redistribution only occurs in the presence of a target motor neuron and parallels the distribution of sensorin protein. Reduction of sensorin mRNA, but not protein, with dsRNA inhibits synapse formation. Our results indicate that synapse formation can alter mRNA localization within individual neurons. They further suggest that translation of a specific localized mRNA, encoding the neuropeptide sensorin, is required for synapse formation between sensory and motor neurons.     

Neurotrophic activities of trk receptors conserved over 600 million years of evolution

The trk family of receptor tyrosine kinases is crucial for neuronal survival in the vertebrate nervous system, however both C. elegans and Drosophila lack genes encoding trks or their ligands. The only invertebrate representative of this gene family identified to date is Ltrk from the mollusk Lymnaea. Did trophic functions of trk receptors originate early in evolution, or were they an innovation of the vertebrates? Here we show that the Ltrk gene conserves a similar exon/intron order as mammalian trk genes in the region encoding defined extracellular motifs, including one exon encoding a putative variant immunoglobulin-like domain. Chimeric receptors containing the intracellular and transmembrane domains of Ltrk undergo ligand-induced autophosphorylation followed by MAP kinase activation in transfected cells. The chimeras are internalized similarly to TrkA in PC12 cells, and their stimulation leads to differentiation and neurite extension. Knock-down of endogenous Ltrk expression compromises outgrowth and survival of Lymnaea neurons cultured in CNS-conditioned medium. Thus, Ltrk is required for neuronal survival, suggesting that trophic activities of the trk receptor family originated before the divergence of molluscan and vertebrate lineages approximately 600 million years ago.     

Nerve growth factor (NGF) induces sprouting of specific neurons of the snail, Lymnaea stagnalis

Nerve growth factor (NGF) was examined for its ability to elicit sprouting by adult molluscan neurons. Motoneurons and interneurons (but not neurosecretory cells) from Lymnaea exhibited a sprouting response to murine 2.5S NGF in defined medium with a half-maximal response at about 150 ng/mL. Furthermore, an NGF antiserum blocked sprouting by all normally responsive neurons. We tested whether an NGF-like molecule is a component of conditioned medium (CM) by attempting to preabsorb its sprout-inducing activity with NGF antiserum. Treatment of CM with immune (but not nonimmune) serum largely blocked the response of motoneurons, but not that of neurosecretory cells, to CM. We conclude that NGF exerts neurotrophic activity on specific adult Lymnaea neurons, and suggest the possibility that an NGF-like molecule may exist in the molluscan nervous system.     

En passant synaptic varicosities form directly from growth cones by transient cessation of growth cone advance but not of actin-based motility.

Formation of terminal synapses at sites such as the neuromuscular junction involves transformation of the motile growth cone into the nonmotile synaptic terminal. However, transformation does not need to be the mechanism when a neurite forms multiple widely spaced synaptic varicosities along a target in an en passant configuration. Synaptic varicosities could form here by specialization of the neurite after the growth cone has advanced past the site. We examined this issue by using cocultures of identified sensory (SN) and motor (L7) neurons from Aplysia. Living SNs were labeled with fluorescent dye and their neurites were observed at high resolution every few minutes growing along the axon of L7, allowing a fine-grained analysis of the behavior of the growth cone at the sites of synapse formation. All varicosities whose formation was observed indeed developed from the growth cone. Sensory varicosities were shown by electron microscopy to contain features characteristic of active zones for transmitter release within a day of their formation on the motor axon. Growth cone advance slowed or stopped transiently during varicosity formation, but the motile activity of the peripheral region of the growth cone (veils and filopodia) was maintained. These results suggest that target "stop signals" involved in the formation of synapses, at least of the en passant variety, may be of a different type from the growth inhibitory molecules, such as the collapsins, which guide axons to their targets.