Directional control of neurite outgrowth from cultured hippocampal neurons is modulated by the lectin concanavalin A

Cell surface carbohydrates play an important role in the regulation of neurite outgrowth during neuronal development. We have investigated the actions of the plant lectin concanavalin A (Con A), a carbohydrate-binding protein, on neurite outgrowth from hippocampal pyramidal neurons in primary cell culture. Neurons plated in culture medium containing nanomolar concentrations of Con A have a larger number of primary neurites arising directly from the cell soma than do neurons plated in culture medium alone. Furthermore, Con A causes counterclock-wise turning of neurites in over 70% of the cultured neurons. Both of these effects of Con A are blocked by the hapten sugar α-methyl-d-mannopyranoside, suggesting that they result from the interaction of Con A with a cell surface carbohydrate. Another lectin with a different sugar specificity, wheat germ agglutinin, does not modulate neurite outgrowth. Analysis of neurite outgrowth using video-enhanced microscopy reveals that the counter-clockwise turning is accompanied by directionally biased extension of filopodia from the growth cones of growing neurites. Treatment of the neurons with cytochalasin, which disrupts actin polymerization, eliminates the neurite turning induced by Con A, suggesting that actin microfilaments are involved in directional control of neurite outgrowth. © 1992 John Wiley & Sons, Inc.     

Neurite outgrowth from hippocampal neurons is promoted by choroid plexus ependymal cells <Emphasis Type="Italic">in vitro</Emphasis>

Choroid plexus ependymal cells (CPECs) were known to promote axonal growth when choroid plexus is grafted into the adult rat spinal cord. The present study was carried out to examine whether CPECs promote axonal outgrowth from neurons derived from the CNS in vitro. Hippocampal neurons were cocultured on CPEC monolayers. After 24 h, neurite extension was evaluated using various parameters in comparison with cultures grown on poly-L-lysine (PLL)-coated plates and cocultures grown on astrocyte monolayers. The primary neurite length and total neurite length were longest in the cocultures with CPECs. The number of primary neurites and the number of branches were larger in the cultures with CPECs than in the cultures on PLL-coated plates, but almost the same as in the cocultures with astrocytes. Next, we examined whether the neurite extension-promoting effect occurring within 24 h is due primarily to contact with the CPECs or to factors secreted by CPECs into the culture medium. The CPEC monolayers were killed by ethanol fixation, and neurons cultured on them. The neurons extended long neurites with elaborate branching, as in the case of cocultures grown on living CPECs. On the other hand, CPEC-conditioned medium exhibited less promoting effect on neurite outgrowth from hippocampal neurons. These results indicate that CPECs have a capacity to promote neurite outgrowth from CNS neurons in vitro, and that surface plasma membrane-bound components of CPECs strongly contribute to the enhancement of neurite outgrowth in the present coculture system.     

Steps in the formation of a bipolar outgrowth pattern by cultured neurons, and their substrate dependence.

We studied the steps in the formation of the bipolar outgrowth pattern of cultured adult Anterior Pagoda (AP) neurons of the leech growing on a central nervous system (CNS) homogenate as substrate. This pattern, which consists of two primary neurites directed in opposite directions plus some bifurcations, resembles their embryonic pattern but is different from the patterns they develop in culture on leech laminin or Concanavalin A as substrates. In eight neurons that were studied, one primary neurite formed and branched several hours before the second one. Time-lapse video analysis showed that between 12 and 36 h of growth, the more proximal branch of the early neurite migrated retrogradely, rotated, and formed the second primary branch. Both neurites elongated until the total neurite length reached 130-160 microm, when the elongation of primary neurites became synchronous with the retraction of secondary processes, suggesting competition. The substrate dependence of these events was tested by plating AP neurons on leech laminin. On this substrate AP neurons produced multiple independent primary neurites with branches. Retraction of some large branches was followed by their regrowth, and did not correlate with the changes in other neurites. We propose that the dynamics in the formation of the bipolar outgrowth pattern of AP neurons arise from inhibitory extracellular matrix molecules, which reduce the synthesis of precursors for neurite formation.     

Sonic Hedgehog Promotes Neurite Outgrowth of Primary Cortical Neurons Through Up-Regulating BDNF Expression

Sonic hedgehog (Shh), a secreted glycoprotein factor, can activate the Shh pathway, which has been implicated in neuronal polarization involving neurite outgrowth. However, little evidence is available about the effect of Shh on neurite outgrowth in primary cortical neurons and its potential mechanism. Here, we revealed that Shh increased neurite outgrowth in primary cortical neurons, while the Shh pathway inhibitor (cyclopamine, CPM) partially suppressed Shh-induced neurite outgrowth. Similar results were found for the expressions of Shh and Patched genes in Shh-induced primary cortical neurons. Moreover, Shh increased the levels of brain-derived neurotrophic factor (BDNF) not only in lysates and in culture medium but also in the longest neurites of primary cortical neurons, which was partially blocked by CPM. In addition, blocking of BDNF action suppressed Shh-mediated neurite elongation in primary cortical neurons. In conclusion, these findings suggest that Shh promotes neurite outgrowth in primary cortical neurons at least partially through modulating BDNF expression.     

Mouse acetylcholinesterase enhances neurite outgrowth of rat R28 cells through interaction with laminin-1

The enzyme acetylcholinesterase (AChE) terminates synaptic transmission at cholinergic synapses by hydrolyzing the neurotransmitter acetylcholine, but can also exert 'non-classical', morpho-regulatory effects on developing neurons such as stimulation of neurite outgrowth. Here, we investigated the role of AChE binding to laminin-1 on the regulation of neurite outgrowth by using cell culture, immunocytochemistry, and molecular biological approaches. To explore the role of AChE, we examined fiber growth of cells overexpressing different forms of AChE, and/or during their growth on laminin-1. A significant increase of neuritic growth as compared with controls was observed for neurons over-expressing AChE. Accordingly, addition of globular AChE to the medium increased total length of neurites. Co-transfection with PRIMA, a membrane anchor of AChE, led to an increase in fiber length similar to AChE overexpressing cells. Transfection with an AChE mutant that leads to the retention of AChE within cells had no stimulatory effect on neurite length. Noticeably, the longest neurites were produced by neurons overexpressing AChE and growing on laminin-1, suggesting that the AChE/laminin interaction is involved in regulating neurite outgrowth. Our findings demonstrate that binding of AChE to laminin-1 alters AChE activity and leads to increased neurite growth in culture. A possible mechanism of the AChE effect on neurite outgrowth is proposed due to the interaction of AChE with laminin-1.     

Glutamate regulates neurite outgrowth of cultured descending brain neurons from larval lamprey

In larval lamprey, descending brain neurons, which regenerate their axons following spinal cord injury, were isolated and examined in cell culture to identify some of the factors that regulate neurite outgrowth. Focal application of 5 mM or 25 mM L-glutamate to single growth cones inhibited outgrowth of the treated neurite, but other neurites from the same neuron were not inhibited, an effect that has not been well studied for neurons in other systems. Glutamate-induced inhibition of neurite outgrowth was abolished by 10 mM kynurenic acid. Application of high potassium media to growth cones inhibited neurite outgrowth, an effect that was blocked by 2 mM cobalt or 100 microM cadmium, suggesting that calcium influx via voltage-gated channels contributes to glutamate-induced regulation of neurite outgrowth. Application of glutamate to growth cones in the presence of 2 microM omega-conotoxin MVIIC (CTX) still inhibited neurite outgrowth, while CTX blocked high potassium-induced inhibition of neurite outgrowth. Thus, CTX blocked virtually all of the calcium influx resulting from depolarization. To our knowledge, this is the first direct demonstration that calcium influx via ligand-gated ion channels can contribute to regulation of neurite outgrowth. Finally, focal application of glutamate to the cell bodies of descending brain neurons inhibited outgrowth of multiple neurites from the same neuron, and this is the first demonstration that multiple neurites can be regulated in this fashion. Signaling mechanisms involving intracellular calcium, similar to those shown here, may be important for regulating axonal regeneration following spinal cord injury in the lamprey.     

Steps in the formation of a bipolar outgrowth pattern by cultured neurons,and their substrate dependence

We studied the steps in the formation of the bipolar outgrowth pattern of cultured adult Anterior Pagoda (AP) neurons of the leech growing on a central nervous system (CNS) homogenate as substrate. This pattern, which consists of two primary neurites directed in opposite directions plus some bifurcations, resembles their embryonic pattern but is different from the patterns they develop in culture on leech laminin or Concanavalin A as substrates. In eight neurons that were studied, one primary neurite formed and branched several hours before the second one. Time‐lapse video analysis showed that between 12 and 36 h of growth, the more proximal branch of the early neurite migrated retrogradely, rotated, and formed the second primary branch. Both neurites elongated until the total neurite length reached 130–160 μm, when the elongation of primary neurites became synchronous with the retraction of secondary processes, suggesting competition. The substrate dependence of these events was tested by plating AP neurons on leech laminin. On this substrate AP neurons produced multiple independent primary neurites with branches. Retraction of some large branches was followed by their regrowth, and did not correlate with the changes in other neurites. We propose that the dynamics in the formation of the bipolar outgrowth pattern of AP neurons arise from inhibitory extracellular matrix molecules, which reduce the synthesis of precursors for neurite formation. © 2002 Wiley Periodicals, Inc. J Neurobiol 50: 106–117, 2002; DOI 10.1002/neu.10017     

Neurite outgrowth induced by the substrate associated material from nonneuronal cells

Cultured embryonic heart cells release a powerful inducer of neurite outgrowth into the surrounding medium. The present report demonstrates that these cells also deposit material which induces neurite outgrowth directly onto their culture substratum. Thus, embryonic heart cells condition both the culture medium and the culture substratum with respect to neurite outgrowth. Conditioned substrata were prepared by incubating heart cell monolayers in EDTA until the cells released from the substratum and were discarded. When dissociated neurons from ciliary or sympathetic chain ganglia were plated in fresh medium onto a conditioned substratum, neurite outgrowth was initiated in 80–95% of the neurons within 60 min. The neurite-inducing activity is trypsin sensitive, but is not inactivated by antibodies to the cell attachment protein fibronectin, by the membrane-solubilizing detergent Triton X-100, or by the enzymes collagenase, RNase, or DNase. The factor in conditioned medium which also induces neurite outgrowth depends for its activity on attachment to an artificial polyornithine substratum, under which condition it appears to promote adhesion of neuronal filopodia to the substratum. Thus, neurite outgrowth in these two culture systems occurs only if the substratum is conditioned by the appropriate extracellular materials: conditioned either directly by the deposition of heart cell products or indirectly by the binding of a conditioned medium factor to the polyornithine substratum. These substratum-conditioning factors may be related to those components of the extracellular matrix which support neurite outgrowth in vivo.     

Ultrastructural localization of lectin-binding sites and laminin-like immunoreactivity in glial cells and neurites growing out from explant cultures of the central nervous system of embryonic locusts

Summary Lectins with different sugar specificities and labeled with horseradish peroxidase or gold were used to study, at the electron-microscopic level, surface glycoconjugates of glial cells and neurites growing out from explant cultures of the central nervous system of embryonic locusts. Differential binding to differentiating glial cells and to neurites was demonstrated. Concanavalin A (Con A) and wheat-germ agglutinin (WGA) bound to glial and neurite surfaces with different degrees of labeling. The formation of glial processes and junctional complexes was invariably accompanied by a corresponding increase of Con A- and WGA-receptors. Peanut agglutinin (PNA) failed to bind to glial cells but strongly stained the plasma membrane of neurite junctions. Lotus tetragonolobus a. (LTA) did not bind either to glial cells or to neurites. In addition, staining with an antibody against laminin showed labeling in areas of neurite outgrowth and neurite interactions; this resembled the localization of PNA receptors. These findings provide evidence for the presence of different carbohydrates at the surface of neurites and glial cells of locust. Their predominant localization in glial processes and neurite junctions suggests that these carbohydrates constitute part of a group adhesion glycoproteins that also includes laminin.     

The regulation of neurite outgrowth, growth cone motility, and electrical synaptogenesis by serotonin

Identified neurons of the buccal ganglion of the snail Helisoma when isolated from their ganglionic environment and plated in cell culture grow new neurites that are tipped with motile growth cones. Addition of the neurotransmitter serotonin to the culture medium surrounding actively growing neurons causes an immediate, premature cessation of neurite elongation in specific identified neurons. Serotonin selectively inhibits neurite extension of neurons B19 and P5 while having no effect on the extension of neuron B5. Coincident with the serotonin evoked inhibition of neurite elongation is an inhibition of growth cone motile activities and a retraction of growth cone filopodia and lamellipodia. One site of serotonin's growth inhibitory actions is directly at the growth cone rather than at the neurites or cell body. A second area of this study concerns connectivity. In Helisoma neurons the formation of electrical synaptic connections critically relies on both potential partner neurons having a mutual interaction of actively growing neurites. Neurons in a nongrowing state do not form electrical synapses (Hadley et al., 1983). As a result of inhibiting neurite extension, serotonin is able to affect synaptogenesis by preventing certain neurons (neurons B19) from forming electrical synaptic connections with other neurons (neurons B5) that are themselves competent to interconnect. Thus, by inhibiting neurite extension, serotonin is capable of regulating both the development of arborizations and the formation of connectivity.     

Characterization of a factor that promotes neurite outgrowth: evidence linking activity to a heparan sulfate proteoglycan

Rat sympathetic neurons, plated onto extracellular matrix produced by cultured bovine corneal endothelial cells, rapidly extended neurites in the absence of nerve growth factor (NGF). The response was unaffected by antiserum to NGF. Rapid outgrowth also occurred when sympathetic neurons were plated onto polylysine-coated surfaces that had been exposed to serum-free medium conditioned by corneal endothelial cells (CMSF). A response was seen even when the neurons were cultured without serum. When plated onto a polylysine-coated dish treated with CMSF over half its surface, only the neurons on the treated half extended neurites. The active factor in CMSF was destroyed by trypsin, acid (pH 1.6), base (pH 12.7), or heating to 80 degrees C; it was stable to heating to 60 degrees C, collagenase, deoxyribonuclease, and neuraminidase. The factor elutes just after the void volume of a Sepharose 6B column. In associative cesium chloride gradients, it sediments as a peak centered at a density of 1.36-1.37, corresponding to a peak of material that can be biosynthetically labeled with [35S]sulfate or [3H]leucine. Material from this fraction was inactivated by heparinase, but not chondroitinase ABC, implying that a heparin sulfate proteoglycan is essential for the factor's activity. Inactivation by contaminants in the heparinase preparation was ruled out. Further purification indicated that the active factor may exist as an aggregate containing a heparin sulfate proteoglycan and other molecules. CMSF also promoted neurite outgrowth by other types of neurons. Furthermore, a variety of cell types were shown to produce factors similar to that in CMSF.     

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.     

Autonomous and non-autonomous regulation of mammalian neurite development by Notch1 and Delta1

BACKGROUND: On the basis of experiments suggesting that Notch and Delta have a role in axonal development in Drosophila neurons, we studied the ability of components of the Notch signaling pathway to modulate neurite formation in mammalian neuroblastoma cells in vitro. RESULTS: We observed that N2a neuroblastoma cells expressing an activated form of Notch, Notch1(IC), produced shorter neurites compared with controls, whereas N2a cell lines expressing a dominant-negative Notch1 or a dominant-negative Delta1 construct extended longer neurites with a greater number of primary neurites. We then compared the effects on neurites of contacting Delta1 on another cell and of overexpression of Delta1 in the neurite-extending cell itself. We found that N2a cells co-cultured with Delta1-expressing quail cells produced fewer and shorter neuritic processes. On the other hand, high levels of Delta1 expressed in the N2a cells themselves stimulated neurite extension, increased numbers of primary neurites and induced expression of Jagged1 and Notch1. CONCLUSIONS: These studies show that Notch signals can antagonize neurite outgrowth and that repressing endogenous Notch signals enhances neurite outgrowth in neuroblastoma cells. Notch signals therefore act as regulators of neuritic extension in neuroblastoma cells. The response of neuritic processes to Delta1 expressed in the neurite was opposite to that to Delta1 contacted on another cell, however. These results suggest a model in which developing neurons determine their extent of process outgrowth on the basis of the opposing influences on Notch signals of ligands contacted on another cell and ligands expressed in the same cell.     

Concanavalin A affects beta-tubulin mRNA expression during neuritic processes of mouse neuroblastoma N18TG2 cells in a different manner from colchicine

Addition of concanavalin A (Con A) to mouse neuroblastoma N18TG2 cells cultured with dibutyryl-cAMP which can stimulate neurite outgrowth, stopped the neuritic processes effectively. The extended neurites showed a gradual retraction for at least 8 hrs after addition of Con A, while addition of colchicine caused rapid retraction of the neurites. Immunocytochemistry showed that the addition of Con A did not disorganize the microtubules but the addition of colchicine did. The increase in beta-tubulin mRNA expression which was observed after cell culture and after stimulation by dB-cAMP was suppressed by the addition of Con A. Con A did not affect the beta-tubulin mRNA expression when the cells had already been cultured, while colchicine drastically decreased it. Thus, Con A appeared to affect the beta-tubulin mRNA expression in a different manner from colchicine, probably through inhibition of cell movement.     

Evidence that calcium may control neurite outgrowth by regulating the stability of actin filaments

We investigated the effects of calcium removal and calcium ionophores on the behavior and ultrastructure of cultured chick dorsal root ganglia (DRG) neurons to identify possible mechanisms by which calcium might regulate neurite outgrowth. Both calcium removal and the addition of calcium ionophores A23187 or ionomycin blocked outgrowth in previously elongating neurites, although in the case of calcium ionophores, changes in growth cone shape and retraction of neurites were also observed. Treatment with calcium ionophores significantly increased growth cone calcium. The ability of the microtubule stabilizing agent taxol to block A23187-induced neurite retraction and the ability of the actin stabilizing agent phalloidin to reverse both A23187-induced growth cone collapse and neurite retraction suggested that calcium acted on the cytoskeleton. Whole mount electron micrographs revealed an apparent disruption of actin filaments in the periphery (but not filopodia) of growth cones that were exposed to calcium ionophores in medium with normal calcium concentrations. This effect was not seen in cells treated with calcium ionophores in calcium-free medium or cells treated with the monovalent cation ionophore monensin, indicating that these effects were calcium specific. Ultrastructure of Triton X-100 extracted whole mounts further indicated that both microtubules and microfilaments may be more stable or extraction resistant after treatments which lower intracellular calcium. Taken together, the data suggest that calcium may control neurite elongation at least in part by regulating actin filament stability, and support a model for neurite outgrowth involving a balance between assembly and disassembly of the cytoskeleton.     

Neurite outgrowth from cultured CNS neurons is promoted by inhibitors of protein and RNA synthesis

We examined the effects of changes caused by the blocking of protein and RNA synthesis on neurite outgrowth from neurons of the central nervous system (CNS) in primary culture. Exposure to cycloheximide and actinomycin-D led to dramatic increases in the length of neurites in cultures of neurons from various rat or chick CNS regions. Inhibitor-induced neurite outgrowth was observed (1) from dopaminergic neurons in mixed cultures of the rat substantia nigra or (2) in pure cultures of rat and chick neurons grown on a polyornithine/laminin substratum. These results suggest that neurite outgrowth from CNS neurons is kept restricted, at least in culture, by the continuous production of a labile neurite-inhibiting protein intrinsic to the neurons, which rapidly decays following inhibition of protein or RNA synthesis. 1994 John Wiley & Sons, Inc.     

Differential neurite outgrowth is required for axon specification by cultured hippocampal neurons

Formation of an axon is the first morphological evidence of neuronal polarization, visible as a profound outgrowth of the axon compared with sibling neurites. One unsolved question on the mechanism of axon formation is the role of axon outgrowth in axon specification. This question was difficult to assess, because neurons freely extend their neurites in a conventional culture. Here, we leveraged surface nano/micro‐modification techniques to fabricate a template substrate for constraining neurite lengths of cultured neurons. Using the template, we asked (i) Do neurons polarize even if all neurites cannot grow sufficiently long? (ii) Would the neurite be fated to become an axon if only one was allowed to grow long? A pattern with symmetrical short paths (20 μm) was used to address the former question, and an asymmetrical pattern with one path extended to 100 μm for the latter. Axon formation was evaluated by tau‐1/MAP2 immunostaining and live‐cell imaging of constitutively‐active kinesin‐1. We found that (1) neurons cannot polarize when extension of all neurites is restricted and that (2) when only a single neurite is permitted to grow long, neurons polarize and the longest neurite becomes the axon. These results provide clear evidence that axon outgrowth is required for its specification.     

Actin in emerging neurites is recruited from a monomer pool

Does actin in the emerging axons of regenerating neurons arise from the assembled or unassembled actin pool in the cell soma? We investigated this question by loading neurons with one of two fluorescently labeled molecules: rhodamine actin (r-actin) and rhodamine phalloidin (r-phalloidin). The assembly behavior of r-actin in vitro was identical to unlabeled actin. R-phalloidin binds tightly only to the filamentous form of actin (F-actin) and stabilizes filaments against disassembly. Hence, r-phalloidin-tagged filaments should be less likely to disassemble than r-actin-tagged filaments. Neurons of 10-d-old chick embryos were loaded with r-actin or r-phalloidin by triturating trypsinized dorsal root ganglia in isotonic sucrose containing the fluorescently tagged molecule. Isolated neurons were plated on glass coverslips in modified L15 medium containing nerve growth factor. Video images of the live cells on a thermoregulated stage were acquired with a computer imaging system. After 24 h in culture, the fluorescence distribution of r-phalloidin and r-actin was examined in live neurons of comparable morphology, neurite outgrowth, and intensity of somal fluorescence. Greater than 90% of the neurons labeled with r-actin (n=81) contained detectable levels of fluorescence in emerging neurite fibers, often extending to the tip of the growing process. Less than 10% of the neurons labeled with r-phalloidin (n=53) contained any fluorescence in the neurite fibers. In those that did contain fluorescence, the r-phalloidin usually was confined to the proximal segment of the neurite, and in no case was it found at the growing tip. Confocal microscopy and cooled CCD imaging of fixed neurons showed that all structures that incorporated r-actin or r-phalloidin also stained with bodipy phallacidin. This colocalization confirms the association of rhodamine-tagged species with F-actin. Our data support a model in which actin, needed in early stages of neurite outgrowth, arises from a pool in the soma that is capable of disassembly.     

Changing interactions between astrocytes and neurons during CNS maturation

The environments of the developing brain and injured adult brain differ in their abilities to support axonal growth. To determine if astrocytes contribute to this difference, neurons were plated onto astrocytes cultured from the neonatal rat cortex and from the injured adult brain. Two patterns of neurite growth were observed in these two astrocyte culture systems. Neurons contacting the neonatal astrocytes had neurites that were twice as long as those contacting the injured adult astrocytes. Furthermore, in cultures with neonatal astrocytes, neurites faithfully followed the astrocytic processes, maximizing their contact, while in cultures of injured adult astrocytes, the neurites had a tendency to cross the processes orthogonally, minimizing their interaction with the astrocytes. When neurons were grown suspended over either neonatal or injured adult astrocytes, no difference in neurite length or the pattern of neurite growth was observed, indicating that neurite growth was not differentially affected by soluble factors released from the two populations of astrocytes. The addition of fetal calf serum, which is known to contain protease inhibitors, did not alter neurite growth when compared to serum-free medium, suggesting that a substantial difference in protease activity does not account for the variations in neurite length observed. Based on these results, it appears that the molecular components of the external surface of injured adult astrocytes do not support neurite growth to the same extent as those found on neonatal astrocytes. The differing abilities of these two populations of cultured astrocytes to support neurite growth in culture may reflect a change in the functional role of these cells that occurs during the development of the central nervous system.     

Fibronectin-like immunoreactivity in Helisoma buccal ganglia: evidence that an endogenous fibronectin-like molecule promotes neurite outgrowth

We examined the distribution of fibronectin-like (FNL) immunoreactivity associated with intact buccal ganglia, cell-cultured buccal ganglia neurons and nonneuronal cells, and brain-conditioned medium from the snail Helisoma. In addition, the possible roles of fibronectin in the regulation of neurite outgrowth were studied. Immunofluorescent staining for FNL antigens revealed intense staining in patches and fibrous arrays over the connective tissue sheaths of buccal ganglia and nerve trunks. Within the ganglia, heavy staining was seen surrounding neurons and in track-like arrangements. In cell cultures, specific staining was associated with nonneuronal cell surfaces and to a lesser degree with the surface of identified neurons. In addition, a noncellular, substrate-bound component of brain-conditioned medium displayed FNL immunoreactivity. Since cultured Helisoma neurons require a substrate-associated, brain-derived conditioning factor (CF) in order to elaborate neurites with motile growth cones, we tested whether the FNL immunoreactive substance might act as a neuritotropic agent. Fibronectin antiserum suppressed, in a dose-dependent manner, the CF-induced sprouting of identified neurons in isolated cell culture. When added at increasing concentrations to neurons already growing in response to CF, fibronectin antiserum exerted a biphasic effect on neurite elongation; outgrowth was accelerated at low, but inhibited at high, antiserum concentrations. In contrast, growth cone structures associated with motility (filopodia and lamellipodia) were progressively reduced by increasing levels of antiserum. A short peptide derived from fibronectin's cell-binding domain (Arg-Gly-Asp-Ser) also greatly reduced neurite outgrowth. The combined results of this study indicate an abundance of FNL immunoreactive molecules within the CNS of Helisoma, their probable production by nonneuronal cells, and their function as a substrate-associated component of CF which promotes growth cone filopodial and lamellipodial activity.