L1 and N-CAM Antibodies Trigger Protein Phosphatase Activity in Growth Cone-Enriched Membranes

Abstract: Triggering of the cell adhesion molecules L1 or N-CAM in a nerve growth cone membrane fraction from fetal rat brain with purified L1 or N-CAM or specific antibodies decreases the steady-state levels of protein tyrosine phosphorylation in the membranes. Here we report that triggering of L1 and N-CAM in the growth cone-enriched membrane fraction with a subset of antibodies directed against the extracellular region of L1 and N-CAM elicited dephosphorylation of endogenous protein substrates, indicating the presence of a cell adhesion molecule-activated phosphatase. The most prominent substrates were a membrane-associated 200-kDa protein and tubulin, both of which were dephosphorylated on tyrosine and serine/threonine residues in response to L1 or N-CAM triggering. The antibody-induced phosphatase was inhibited by agents that blocked tyrosine and serine/threonine phosphatases, including sodium orthovanadate, vanadyl sulfate, zinc cations, heparin, and sodium pyrophosphate. Purified L1 and N-CAM fragments and other antibodies reacting with the extracellular region of these adhesion molecules did not activate the phosphatase but did inhibit tyrosine phosphorylation. These properties suggested that triggering of L1 and N-CAM can lead to either phosphatase activation or tyrosine kinase inhibition in growth cone membranes. These findings implicate protein phosphatases in addition to tyrosine kinases as components of L1 and N-CAM intracellular signaling pathways in growth cones.     

Antibodies that recognize astrotactin block granule neuron binding to astroglia

To provide a rapid, specific assay for receptor systems involved in the binding of cerebellar granule neurons to astroglia, granule cells, purified from early postnatal mice, or from E15-E16 chicks, were radiolabeled with [35S]methionine and plasma membranes were prepared. The kinetics of binding of radiolabeled material to primary mouse or chick glia or to the mouse G26-24 astrocytoma cell line was measured in the presence or absence of antibodies against astrotactin, neural cell adhesion molecules, cadherins, or integrins. Addition of Fab fragments of astrotactin antibodies reduced the amount of granule cell membrane binding to astroglia by 70%. In contrast, Fab fragments of antibodies against the neural adhesion molecules N-CAM, L1, and N-cadherin and against integrin did not reduce the level of granule cell membrane binding to astroglia. Combinations of antibodies against N-CAM, L1, N-cadherin, and integrin also did not impair neuron binding to glia.     

Immunoelectron microscopic localization of the neural cell adhesion molecules L1 and N-CAM during postnatal development of the mouse cerebellum

The cellular and subcellular localization of the neural cell adhesion molecules L1 and N-CAM was studied by pre- and postembedding immunoelectron microscopic labeling procedures in the developing mouse cerebellar cortex. The salient features of the study are: L1 displays a previously unrecognized restricted expression by particular neuronal cell types (i.e., it is expressed by granule cells but not by stellate and basket cells) and by particular subcellular compartments (i.e., it is expressed on axons but not on dendrites or cell bodies of Purkinje cells). L1 is always expressed on fasciculating axons and on postmitotic, premigratory, and migrating granule cells at sites of neuron-neuron contact, but never at contact sites between neuron and glia, thus strengthening the view that L1 is not involved in granule cell migration as a neuron-glia adhesion molecule. While N-CAM antibodies reacting with the three major components of N-CAM (180, 140, and 120 kD) show a rather uniform labeling of all cell types, antibodies to the 180-kD component (N-CAM180) stain only the postmigratory granule cell bodies supporting the notion that N-CAM180, the N-CAM component with the longest cytoplasmic domain, is not expressed before stable cell contacts are formed. Furthermore, N-CAM180 is only transiently expressed on Purkinje cell dendrites. N-CAM is present in synapses on both pre- and post-synaptic membranes. L1 is expressed only preterminally and not in the subsynaptic membranes. These observations indicate an exquisite degree of fine tuning in adhesion molecule expression during neural development and suggest a rich combinatorial repertoire in the specification of cell surface contacts.     

Topography of cell ahesion molecules CD9, CD24, L1 and N-CAM on the surface of neuroblastoma cells studied using chemical cross linking

Cell-adhesion molecules are thought to play crucial roles in development and plasticity in the nervous system. Four neural cell adhesion molecules CD9, CD24, L1 and N-CAM are associated in the surface membrane of cultured neuroblastoma cells as studied by chemical cross-linking with bifunctional reagent 3,3'-dithiobis (sulphosuccinimidyl-propionate) followed by a subsequent immunodetection using antibodies directed against the above molecules. We obtained direct evidence of CD9 and L1, but not CD9 and N-CAM clasterisation, also interactions of CD24 with L1, CD24 with N-CAM and some others. These observations illustrate topography of neural cell adhesion molecules located in the vicinity to each other and imply the basis for their functional cooperativity.     

Functional cooperation between the neural adhesion molecules L1 and N- CAM is carbohydrate dependent

The neural cell adhesion molecules L1 and N-CAM have been suggested to interact functionally by formation of a complex between the two molecules (Kadmon, G., A. Kowitz, P. Altevogt, and M. Schachner. 1990. J. Cell Biol. 110:193-208). To determine the molecular mechanisms underlying this functional cooperation, we have studied the contribution of carbohydrates to the association of the two molecules at the cell surface. Aggregation or adhesion between L1- and N-CAM-positive neuroblastoma N2A cells was reduced when the synthesis of complex and/or hybrid glycans was modified by castanospermine. Fab fragments of polyclonal antibodies to L1 inhibited aggregation and adhesion of castanospermine-treated cells almost completely, whereas untreated cells were inhibited by approximately 50%. Fab fragments of polyclonal antibodies to N-CAM did not interfere with the interaction between castanospermine-treated cells, whereas they inhibited aggregation or adhesion of untreated cells by approximately 50%. These findings indicate that cell interactions depending both on L1 and N-CAM ("assisted homophilic" binding) can be reduced to an L1-dominated interaction ("homophilic binding"). Treatment of cells with the carbohydrate synthesis inhibitor swainsonine did not modify cell aggregation in the absence or presence of antibodies compared with untreated cells, indicating that castanospermine-sensitive, but swainsonine-insensitive glycans are involved. To investigate whether the appropriate carbohydrate composition is required for an association of L1 and N-CAM in the surface membrane (cis-interaction) or between L1 on one side and L1 and N-CAM on the other side of interacting partner cells (trans-interaction), an L1-positive lymphoid tumor cell line was coaggregated with and adhered to neuroblastoma cells in the various combinations of castanospermine-treated and untreated cells. The results show that it is the cis-interaction between L1 and N-CAM that depends on the appropriate carbohydrate structures.     

The neural cell adhesion molecule N-CAM enhances L1-dependent cell-cell interactions

On neural cells, the cell adhesion molecule L1 is generally found coexpressed with N-CAM. The two molecules have been suggested, but not directly shown, to affect each other's function. To investigate the possible functional relationship between the two molecules, we have characterized the adhesive interactions between the purified molecules and between cultured cells expressing them. Latex beads were coated with purified L1 and found to aggregate slowly. N-CAM-coated beads did not aggregate, but did so after addition of heparin. Beads coated with both L1 and N-CAM aggregated better than L1-coated beads. Strongest aggregation was achieved when L1-coated beads were incubated together with beads carrying both L1 and N-CAM. In a binding assay, the complex of L1 and N-CAM bound strongly to immobilized L1, but not to the cell adhesion molecules J1 or myelin-associated glycoprotein. N-CAM alone did not bind to these glycoproteins. Cerebellar neurones adhered to and sent out processes on L1 immobilized on nitrocellulose. N-CAM was less effective as substrate. Neurones interacted most efficiently with the immobilized complex of L1 and N-CAM. They adhered to this complex even when its concentration was at least 10 times lower than the lowest concentration of L1 found to promote adhesion. The complex became adhesive for cells only when the two glycoproteins were preincubated together for approximately 30 min before their immobilization on nitrocellulose. The adhesive properties between cells that express L1 only or both L1 and N-CAM were also studied. ESb-MP cells, which are L1-positive, but N-CAM negative, aggregated slowly under low Ca2+. Their aggregation could be completely inhibited by antibodies to L1 and enhanced by addition of soluble N-CAM to the cells before aggregation. N2A cells, which are L1 and N-CAM positive aggregated well under low Ca2+. Their aggregation was partially inhibited by either L1 or N-CAM antibodies and almost completely by the combination of both antibodies. N2A and ESb-MP cells coaggregated rapidly and their interaction was similarly inhibited by L1 and N-CAM antibodies. These results indicate that L1 is involved in two types of binding mechanisms. In one type, L1 serves as its own receptor with slow binding kinetics. In the other, L1 is modulated in the presence of N-CAM on one cell (cis-binding) to form a more potent receptor complex for L1 on another cell (trans-binding).     

Studies of adhesion molecules mediating interactions between cells of peripheral nervous system indicate a major role for L1 in mediating sensory neuron growth on Schwann cells in culture

The involvement of the adhesion molecules L1, N-CAM, and J1 in adhesion and neurite outgrowth in the peripheral nervous system was investigated. We prepared Schwann cells and fibroblasts (from sciatic nerves) and neurons (from dorsal root ganglia) from 1-d mice. These cells were allowed to interact with each other in a short-term adhesion assay. We also measured outgrowth of dorsal root ganglion neurons on Schwann cell and fibroblast monolayers. Schwann cells (which express L1, N-CAM, and J1) adhered most strongly to dorsal root ganglion neurons by an L1-dependent mechanism and less by N-CAM and J1. Schwann cell-Schwann cell adhesion was mediated by L1 and N-CAM, but not J1. Adhesion of fibroblasts (which express N-CAM, but not L1 or J1) to neurons or Schwann cells was mediated by L1 and N-CAM and not J1. However, inhibition by L1 and N-CAM antibodies was found to be less pronounced with fibroblasts than with Schwann cells. N-CAM was also strongly involved in fibroblast-fibroblast adhesion. Neurite outgrowth was most extensive on Schwann cells and less on fibroblasts. A difference in extent of neurite elongation was seen between small- (10-20 microns) and large- (20-35 microns) diameter neurons, with the larger neurons tending to exhibit longer neurites. Fab fragments of polyclonal L1, N-CAM, and J1 antibodies exerted slightly different inhibitory effects on neurite outgrowth, depending on whether the neurites were derived from small or large neurons. L1 antibodies interfered most strikingly with neurite outgrowth on Schwann cells (inhibition of 88% for small and 76% for large neurons), while no inhibition was detectable on fibroblasts. Similarly, although to a smaller extent than L1, N-CAM appeared to be involved in neurite outgrowth on Schwann cells and not on fibroblasts. Antibodies to J1 only showed a very small effect on neurite outgrowth of large neurons on Schwann cells. These observations show for the first time that identified adhesion molecules are potent mediators of glia-dependent neurite formation and attribute to L1 a predominant role in neurite outgrowth on Schwann cells which may be instrumental in regeneration.     

Expression of the cell adhesion molecules N-CAM and L1 in B16 melanoma cells

The cell adhesion molecules N-CAM and L1 are important for cell-cell recognition and cell migration and so may be involved in the metastatic process. We have studied the biosynthesis of N-CAM and L1 in the B16 melanoma cell lines B16-F1 and B16-F10 which differ in metastatic capacity. N-CAM was synthesised as two glycosylated polypeptides with Mr of 150,000 and 210,000; L1 was synthesised as one polypeptide with Mr of 215,000. In fetal neurons N-CAM is synthesised as a 135,000 and a 200,000 Mr polypeptide and L1 as a 200,000 Mr polypeptide. Thus, the Mr of N-CAM and L1 in tumour cells appeared to be 10,000-15,000 higher than in the normal cells. L1 was phosphorylated in the tumour cells as in neurons. The tumour cells also phosphorylated the 210,000 Mr N-CAM polypeptide, whereas no phosphorylation of the 150,000 Mr polypeptide was observed. In neuronal cells both the corresponding polypeptides are phosphorylated and thus the biosynthesis of N-CAM in tumour cells seem to differ from that in neuronal cells with regard to phosphorylation. No differences in biosynthesis of N-CAM or L1 were apparent between the two tumour cell lines, B16-F1 and B16-F10.     

Interactions of the chondroitin sulfate proteoglycan phosphacan, the extracellular domain of a receptor-type protein tyrosine phosphatase, with neurons, glia, and neural cell adhesion molecules

Phosphacan is a chondroitin sulfate proteoglycan produced by glial cells in the central nervous system, and represents the extracellular domain of a receptor-type protein tyrosine phosphatase (RPTP zeta/beta). We previously demonstrated that soluble phosphacan inhibited the aggregation of microbeads coated with N-CAM or Ng-CAM, and have now found that soluble 125I-phosphacan bound reversibly to these neural cell adhesion molecules, but not to a number of other cell surface and extracellular matrix proteins. The binding was saturable, and Scatchard plots indicated a single high affinity binding site with a Kd of approximately 0.1 nM. Binding was reduced by approximately 15% after chondroitinase treatment, and free chondroitin sulfate was only moderately inhibitory, indicating that the phosphacan core glycoprotein accounts for most of the binding activity. Immunocytochemical studies of embryonic rat spinal phosphacan, Ng-CAM, and N-CAM have overlapping distributions. When dissociated neurons were incubated on dishes coated with combinations of phosphacan and Ng-CAM, neuronal adhesion and neurite growth were inhibited. 125I-phosphacan bound to neurons, and the binding was inhibited by antibodies against Ng-CAM and N-CAM, suggesting that these CAMs are major receptors for phosphacan on neurons. C6 glioma cells, which express phosphacan, adhered to dishes coated with Ng-CAM, and low concentrations of phosphacan inhibited adhesion to Ng-CAM but not to laminin and fibronectin. Our studies suggest that by binding to neural cell adhesion molecules, and possibly also by competing for ligands of the transmembrane phosphatase, phosphacan may play a major role in modulating neuronal and glial adhesion, neurite growth, and signal transduction during the development of the central nervous system.     

Regulation of neural cell adhesion molecule expression on cultured mouse Schwann cells by nerve growth factor.

Schwann cells from early postnatal mouse sciatic nerve were obtained as a homogenous population and shown by indirect immunofluorescence to express the neural cell adhesion molecules L1, N-CAM and J1 and their common carbohydrate epitope L2/HNK-1. L1 and N-CAM are synthesized in molecular forms that are slightly different from those expressed by small cerebellar neurons or astrocytes. As in astrocytes, the J1 antigen is expressed by Schwann cells in multiple forms generally ranging from 160 to 230 kd in the reduced state. J1 is secreted by Schwann cells in a 230-kd mol. wt form. Expression of L1 by Schwann cells can be regulated by nerve growth factor (NGF). L1 expression on the cell surface is increased 1.6-fold in the presence of NGF after 3 days of maintenance in vitro and 3-fold after 16 days. NGF does not change expression of N-CAM. The glia-derived neurite-promoting factor (GdNPF) increases L1 expression by a factor of 1.9 and decreases N-CAM expression by a factor of 0.4 after 3 days in vitro. J1 expression on Schwann cell surfaces remains unchanged in the presence of NGF or GdNPF. Antibodies to NGF abolish the influence of NGF on L1 expression. Addition of NGF antibodies to the Schwann cell cultures without exogenously added NGF decreases L1 expression, indicating that Schwann cells secrete NGF that may influence L1 expression by an autocrine mechanism. Our experiments show for the first time that cell adhesion molecule expression on a non-neuronal cell, the Schwann cell, can be directly regulated by the neurotrophic factor NGF. These observations indicate a considerable degree of 'plasticity' of peripheral glia in regulating cell adhesion molecule expression.     

Cytochalasin D disrupts the restricted localization of N-CAM,but not of L1, at sites of Schwann cell—neurite and Schwann cell–Schwann cell contact in culture

The neural recognition molecules L1 and N-CAM have been shown to be preferentially localized at sites of Schwann cell-to-neurite and Schwann cell-to-Schwann cell contact in vitro. In the present study, we investigated the mechanisms underlying the restricted expression of these molecules at the Schwann cell surface, focusing on the possible role of actin filaments. Co-cultures consisting of Schwann cells from newborn mice and explants of dorsal root ganglia from chicken embryos were maintained in the absence or presence of cytochalasin D, an agent disrupting actin filaments. Immunoelectron microscopy with mouse-specific antibodies was carried out to quantify the restricted localization of L1 and N-CAM at the Schwann cell surface in contact with neurites. After 2 days of co-culturing in the absence of cytochalasin D, approximately 65% of the cell–cell contacts showed a restricted immunoreactivity for L1 and N-CAM. The accumulation of L1 at contact sites was unchanged in cytochalasin D-treated co-cultures, while the agent strongly reduced the restricted localization of N-CAM to 20% of all cell–cell contacts. The disruption of N-CAM accumulation appeared to be rapid and occurred within 5 h of cytochalasin D treatment. These results indicate that the restricted localization of N-CAM, but not of L1, is sensitive to cytochalasin D treatment, suggesting a dependence on the integrity of the actin network. Thus, different mechanisms may regulate the subcellular distribution of cell adhesion molecules in Schwann cells.     

Effects of antibodies against N-cadherin and N-CAM on the cranial neural crest and neural tube.

We have examined the distribution and function of the defined cell adhesion molecules, N-cadherin and N-CAM, in the emigration of cranial neural crest cells from the neural tube in vivo. By immunocytochemical analysis, both N-cadherin and N-CAM were detected on the cranial neural folds prior to neural tube closure. After closure of the neural tube, presumptive cranial neural crest cells within the dorsal aspect of the neural tube had bright N-CAM and weak N-cadherin immunoreactivity. By the 10- to 11-somite stage, N-cadherin was prominent on all neural tube cells with the exception of the dorsal-most cells, which had little or no detectable immunoreactivity. N-CAM, but not N-cadherin, was observed on some migrating neural crest cells after their departure from the cranial neural tube. To examine the functional significance of these molecules, perturbation experiments were performed by injecting antibodies against N-CAM or N-cadherin into the cranial mesenchyme adjacent to the midbrain. Fab' fragments or whole IgGs of monoclonal and polyclonal antibodies against N-CAM caused abnormalities in the cranial neural tube and neural crest. Predominantly observed defects included neural crest cells in ectopic locations, both within and external to the neural tube, and mildly deformed neural tubes containing some dissociating cells. A monoclonal antibody against N-cadherin also disrupted cranial development, with the major defect being grossly distorted neural tubes and some ectopic neural crest cells outside of the neural tube. In contrast, nonblocking N-CAM antibodies and control IgGs had few effects. Embryos appeared to be sensitive to the N-CAM and N-cadherin antibodies for a limited developmental period from the neural fold to the 9-somite stage, with older embryos no longer displaying defects after antibody injection. These results suggest that the cell adhesion molecules N-CAM and N-cadherin are important for the normal integrity of the cranial neural tube and for the emigration of neural crest cells. Because cell-matrix interactions also are required for proper emigration of cranial neural crest cells, the results suggest that the balance between cell-cell and cell-matrix adhesion may be critical for this process.     

Distribution and possible interactions of actin-associated proteins and cell adhesion molecules of nerve growth cones

Actin filaments and their interactions with cell surface molecules have key roles in tissue cell behaviour. Axonal pathfinding during embryogenesis, an especially complex cell behaviour, is based on the migration of nerve growth cones. We have used fluorescence immunocytochemistry to examine the distribution in growth cones, their filopodia and lamellipodia of several actin-associated proteins and nerve cell adhesion molecules. The leading margins of chick dorsal root ganglion nerve growth cones and their protrusions stain strongly for f-actin, filamin, alpha-actinin, myosin, tropomyosin, talin and vinculin. MAP2 is absent from DRG growth cones, and staining for spectrin fodrin extends into growth cones, but not along filopodia. Thus, organization of the leading margins of growth cones may strongly resemble the leading lamella of migrating fibroblasts. The adhesion-mediating molecules integrin, L1, N-CAM and A-CAM are all found on DRG neurites and growth cones. However, filopodia stain relatively more strongly for integrin and L1 than for A-CAM or N-CAM. In fact, the 180 X 10(3) Mr form of N-CAM may be absent from most of the length of filopodia. DRG neurones cultured in cytochalasin B display differences in immunofluorescence staining which further emphasize that these adhesion molecules interact differentially with the actin filament system of migrating growth cones. Several models for neuronal morphogenesis emphasize the importance of regulation of the expression of adhesion molecules. Our results support hypotheses that cellular distribution and transmembrane interactions are key elements in the functions of these adhesion molecules during axonal pathfinding.     

Comparison of two cell surface molecules involved in neural cell adhesion

Two cell surface molecules found in mouse brain, N-CAM and the L1 antigen, were compared in terms of their cell adhesion function, polypeptide structures, antigenic determinants and distribution in cerebellar tissue. Fab fragments of polyclonal antibodies to either N-CAM or L1 antigen only partially inhibited the rate of calcium-independent aggregation of neuroblastoma N2A cells, whereas complete and more efficient inhibition was obtained when they were used in combination. Despite the functional similarity, comparison of the electrophoretic behaviour of the purified molecules and of their proteolytic fragments shows that the L1 antigen polypeptide is distinct from that of N-CAM. In addition, no antigenic cross-reactivity was detected between the two molecules. In cryostat sections of cerebellum from young post-natal mice, N-CAM was found to be present in all cell and neurite layers, whereas L1 antigen was expressed only in regions containing post-mitotic cells. These results indicate that two chemically and histochemically distinct cell surface polypeptides can contribute to the calcium-independent adhesiveness of neural cells, and suggest that their differential expression might cause adhesive specificity among cells of developing neural tissues.     

Cell adhesion molecules in the early developing mouse retina: Retinal neurons show preferential outgrowth in vitro on L1 but not N-CAM

Both L1 and N-CAM are present on optic axons early in the developing mouse retina and optic nerve. In in vitro assays on substrates of purified cell adhesion molecules cells derived from E13 mouse retinae showed vigorous neurite extension on L1 but not on N-CAM. Although retinal neurons on N-CAM showed only limited attachment to the substrate, they were able to form lamellipodia immediately around the cell perimeter. In contrast, similarly derived cortical cells showed extensive neurite outgrowth on both substrates. Under these culture conditions, nearly all of the L1 and N-CAM present in the cell membrane appeared to be sequestered on the lower surface of the growth cones and neurites, indicating that most of these cell adhesion molecules were involved in homophilic interactions. Our results suggest differential roles for L1 and N-CAM in intitiation and establishment of the optic pathway. © 1994 John Wiley & Sons, Inc.     

Expression of several adhesive macromolecules (N-CAM, L1, J1, NILE, uvomorulin, laminin, fibronectin, and a heparan sulfate proteoglycan) in embryonic, adult, and denervated adult skeletal muscle

Levels of the neural cell adhesion molecule N-CAM in muscle are regulated in parallel with the susceptibility of muscle to innervation: N-CAM is abundant on the surface of early embryonic myotubes, declines in level as development proceeds, reappears when adult muscles are denervated or paralyzed, and is lost after reinnervation (Covault, J., and J. R. Sanes, 1985, Proc. Natl. Acad. Sci. USA, 82:4544-4548). Here we used immunocytochemical methods to compare this pattern of expression with those of several other molecules known to be involved in cellular adhesion. Laminin, fibronectin, and a basal lamina-associated heparan sulfate proteoglycan accumulate on embryonic myotubes after synapse formation, and their levels change little after denervation. L1, J1, nerve growth factor-inducible large external protein, uvomorulin, and a carbohydrate epitope (L2/HNK-1) shared by several adhesion molecules are undetectable on the surface of embryonic, perinatal, adult, or denervated adult muscle fibers. Thus, of the molecules tested, only N-CAM appears on the surface of muscle cells in parallel with the ability of the muscle cell surface to accept synapses. However, four antigens--N-CAM, J1, fibronectin, and a heparan sulfate proteoglycan--accumulate in interstitial spaces near denervated synaptic sites; regenerating axons traverse these spaces as they preferentially reinnervate original synaptic sites. Of particular interest is J1, antibodies to which block adhesion of central neurons to astrocytes (Kruse, J., G. Keihauer, A. Faissner, R. Timpl, and M. Schachner, 1985, Nature (Lond.), 316:146-148). J1 is associated with collagen and other fibrils in muscle and thus may be an extracellular matrix molecule employed in both the central and peripheral nervous systems.     

Neural cell adhesion molecules influence second messenger systems

We have investigated the influence of the neural cell adhesion molecules L1 and N-CAM on second messenger systems using a PC12 rat pheochromocytoma cell line as a model and triggering cell surface receptors by specific antibody binding. Antibodies directed against L1 and N-CAM, but not against other cell surface components, reduce intracellular levels of the inositol phosphates IP2 and IP3, while intracellular levels of cAMP are unaffected. Antibodies against L1 and N-CAM also reduce intracellular pH and increase intracellular Ca2+ by opening Ca2+ channels in a pertussis toxin-inhibitable manner, suggesting the involvement of a G protein in the signal transduction process. Cross-linking of the adhesion molecules on the surface membrane is not required for the effects to occur. Furthermore, adhesion of single PC12 cells to each other elicits effects on intracellular pH and Ca2+ similar to those seen after application, underscoring the physiological significance of the observed changes.     

Sensitivity of neurite outgrowth to microfilament disruption varies with adhesion molecule substrate

Interactions between the cytoskeleton and cell adhesion molecules are presumed responsible for neurite extension. We have examined the role of microfilaments in neurite outgrowth on the cell adhesion molecules L1, P84, N-CAM, and on laminin. Cerebellar neurons growing on each substrate exhibited differing growth cone morphologies and rates of neurite extension. Growth of neurites in the presence of cytochalasin B (CB) was not inhibited on substrates of L1 or P84 but was markedly inhibited on N-CAM. Neurons on laminin were initially unable to extend neurites in the presence of CB but recovered this ability within 9 h. These studies suggest that neurite outgrowth mediated by different cell adhesion molecules proceeds via involvement of distinct cytoskeletal interactions. © 1993 John Wiley & Sons, Inc.     

Astrocyte-derived TGF-beta 2 and NGF differentially regulate neural recognition molecule expression by cultured astrocytes

Because of the importance of neural recognition molecules expressed by glial cells to mediate interactions with neurons, growth factors and cytokines known to be functional during morphogenesis and in diseases of the nervous system were studied for their effects on recognition molecule expression by cultured immature and mature astrocytes from several brain regions. In cultures of immature astrocytes, transforming growth factors-beta 1 (TGF-beta 1) and -beta 2 (TGF-beta 2) and nerve growth factor (NGF) increased expression of the neural adhesion molecule L1, leading to a glia-mediated L1-specific increase in neurite outgrowth of dorsal root ganglion neurons on the astrocyte substrate. L1 expression induced by TGF-beta was inhibited by addition of antibodies to NGF, suggesting that TGF-beta influences L1 expression by modulating production of NGF by astrocytes. TGF-beta 1 and -beta 2 decreased expression of N-CAM by immature astrocytes. Since N-CAM expression was not affected by NGF and antibodies to NGF did not abolish the TGF-beta-induced decrease in N-CAM expression, NGF did not appear to be the mediator for regulating expression of N-CAM. Expression of the adhesion molecule on glia (AMOG) was not affected by any factor. NGF and TGF-beta 2 in latent form, but not TGF-beta 1 were found in the culture supernatants. Addition of interferon-gamma (IFN-gamma), interleukin-1 beta (IL-1 beta), interleukin-6 (IL-6), platelet-derived growth factor (PDGF), or basic fibroblast growth factor (bFGF) to the cultures did not change recognition molecule expression. REcognition molecule expression by mature astrocytes was not found to be modified by any of the factors tested. In view of the observation that levels of L1 and N-CAM expression correlated with the presence of TGF-beta 2 and NGF in the culture supernatants of immature astrocytes, an autocrine regulatory mechanism for recognition molecule expression by these cells is suggested to play a crucial role in regulation of neuron-glia interactions.