Neuronal process outgrowth of human sensory neurons on monolayers of cells transfected with cDNAs for five human N-CAM isoforms

Full length cDNAs for a variety of human N-CAM isoforms have been transfected into mouse L-cells and/or 3T3 cells. Three independent clones of each cell line that were shown to express human N-CAM were tested for their ability to support the morphological differentiation of sensory neurons. The cell surface expression of N-CAM isoforms, linked to the membrane directly by an integral transmembrane spanning domain or indirectly via covalent attachment to a glycosyl-phosphatidylinositol moiety, were consistently found to be associated with a significant increase in the morphological differentiation of both human and rat dorsal root ganglion neurons. Modification of the extracellular structure of both classes of N-CAM, consequent to the expression of a glycosylated 37-amino acid sequence normally found expressed exclusively in muscle N-CAM isoforms did not obviously affect the ability of transfected cells to support increased neuronal differentiation. 3T3 cells that were transfected with a full length cDNA encoding a secreted N-CAM isoform, and that have previously been shown to secrete N-CAM into the growth media rather than link it to the membrane did not significantly differ from control cells in their ability to support neuronal differentiation. These data provide direct evidence for both transmembrane and lipid-linked N-CAM isoforms being components of the regulatory machinery that determines neuronal morphology and process outgrowth.     

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.     

L1-mediated axon outgrowth occurs via a homophilic binding mechanism

The molecular mechanism by which the L1 cell adhesion molecule mediates neurite outgrowth has been examined. Purified L1 from mouse and L1 from chick brain were attached to nitrocellulose dishes. Both chick and mouse neurons were able to adhere to purified mouse L1 and chick L1. Both molecules promoted neurite extension from chick and mouse neurons. Addition of Fabs specific for chick L1 to the cultures inhibited chick neurite outgrowth on both mouse L1 and chick L1. These findings suggest that L1-like molecules support neurite outgrowth via a "homophilic" binding mechanism.     

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.     

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.     

Axonal Glycoproteins with Immunoglobulin- and Fibronectin Type III-Related Domains in Vertebrates: Structural Features, Binding Activities, and Signal Transduction

Abstract: The L1- and F11-like axonal glycoproteins, implicated in neurite outgrowth and fasciculation, are members of the Ig superfamily comprising multiple fibronectin type III-like domains. Their Ig-like and fibronectin type III-related domains are likely to be composed of seven β-strands arranged in two opposing β-sheets of highly similar topology. Whereas the F11-like molecules lack a transmembrane sequence and are anchored in the plasma membrane by a glycosylphosphatidylinositol, the L1 -like molecules comprise cytoplasmic domains with highly conserved sequence motifs. Most of the latter proteins occur in different isoforms generated by alternative pre-mRNA splicing, which has not been documented for molecules of the F11 subgroup. L1 -like proteins undergo heterophils as well as homophilic interactions, whereas only the former mode of binding was observed for F11 -like proteins. Evidence is accumulating that these Ig superfamily molecules with fibronectin type III-like domains are interacting in a complex manner with each other and molecules of the extracellular matrix. Investigations assigning structure to function reveal that their individual extracellular domains serve distinct binding activities. Recent studies also suggest that L1 and NCAM are implicated in the transduction of transmembrane signals.     

Critical and optimal Ig domains for promotion of neurite outgrowth by L1/Ng-CAM

Mammalian L1 and avian Ng-CAM are homologous neural cell adhesion molecules (CAMs) that promote neurite outgrowth and cell adhesion in most neurons. Previous attempts to map these activities to discrete regions in the CAMs have suggested the involvement of a variety of different domains. However, these studies mainly used bacterially expressed proteins that were much less active on a molar basis than the native molecules. To define regions that are critical for maximal neurite outgrowth, we constructed and tested a panel of eukaryotically expressed proteins containing various extracellular segments of human L1 (hL1) or Ng-CAM. Our results indicate that Ig domains 1-4 of hL1 are critical for homophilic binding and neurite outgrowth; however this segment is less potent than the entire extracellular region. Optimal neurite outgrowth activity was seen with proteins containing all six Ig domains of hL1 or Ng-CAM. The adhesive properties of hL1 fragments correlated tightly with their neurite outgrowth activities, suggesting that these two processes are closely linked. These results suggest that Ig domains 1-4 form a structural cassette responsible for hL1 homophilic binding, while Ig domains 1-6 represent a functional region for optimal promotion of neurite outgrowth in vitro and possibly in vivo.     

Neurite outgrowth in response to transfected N-CAM and N-cadherin reveals fundamental differences in neuronal responsiveness to CAMs

Different neuronal populations were used to compare the neurite outgrowth-promoting activities of N-CAM and N-cadherin expressed via gene transfer on the surface of nonneuronal cells. In contrast to a previously reported developmental loss of retinal ganglion cell responsiveness to N-CAM, these cells exhibited an increased and maintained responsiveness to N-cadherin over the same developmental period (E6-E11). N-CAM and N-cadherin responses could be specifically inhibited by their own antibodies, but not by antisera to the beta 1 integrin family or the L1/G4 glycoprotein. Cerebellar neurons showed qualitative differences in the nature of the dose-response curves for transfected N-CAM expression (highly cooperative) versus N-cadherin expression (linear). In addition "subthreshold" levels of N-CAM expression, which do not normally support neurite outgrowth, did so when coexpressed with functional levels of N-cadherin. These studies show fundamental differences in neuronal responsiveness to cell adhesion molecules and suggest a more dynamic regulation for N-CAM-dependent neurite outgrowth than for N-cadherin-dependent outgrowth.     

Critical and optimal Ig domains for promotion of neurite outgrowth by L1/Ng‐CAM

Mammalian L1 and avian Ng‐CAM are homologous neural cell adhesion molecules (CAMs) that promote neurite outgrowth and cell adhesion in most neurons. Previous attempts to map these activities to discrete regions in the CAMs have suggested the involvement of a variety of different domains. However, these studies mainly used bacterially expressed proteins that were much less active on a molar basis than the native molecules. To define regions that are critical for maximal neurite outgrowth, we constructed and tested a panel of eukaryotically expressed proteins containing various extracellular segments of human L1 (hL1) or Ng‐CAM. Our results indicate that Ig domains 1–4 of hL1 are critical for homophilic binding and neurite outgrowth; however this segment is less potent than the entire extracellular region. Optimal neurite outgrowth activity was seen with proteins containing all six Ig domains of hL1 or Ng‐CAM. The adhesive properties of hL1 fragments correlated tightly with their neurite outgrowth activities, suggesting that these two processes are closely linked. These results suggest that Ig domains 1–4 form a structural cassette responsible for hL1 homophilic binding, while Ig domains 1–6 represent a functional region for optimal promotion of neurite outgrowth in vitro and possibly in vivo. © 2000 John Wiley & Sons, Inc. J Neurobiol 42: 287–302, 2000     

Cosignaling of NCAM via lipid rafts and the FGF receptor is required for neuritogenesis

The neural cell adhesion molecule (NCAM) has been reported to stimulate neuritogenesis either via nonreceptor tyrosine kinases or fibroblast growth factor (FGF) receptor. Here we show that lipid raft association of NCAM is crucial for activation of the nonreceptor tyrosine kinase pathway and induction of neurite outgrowth. Transfection of hippocampal neurons of NCAM-deficient mice revealed that of the three major NCAM isoforms only NCAM140 can act as a homophilic receptor that induces neurite outgrowth. Disruption of NCAM140 raft association either by mutation of NCAM140 palmitoylation sites or by lipid raft destruction attenuates activation of the tyrosine focal adhesion kinase and extracellular signal-regulated kinase 1/2, completely blocking neurite outgrowth. Likewise, NCAM-triggered neurite outgrowth is also completely blocked by a specific FGF receptor inhibitor, indicating that cosignaling via raft-associated kinases and FGF receptor is essential for neuritogenesis.     

Neurite outgrowth in response to transfected N-CAM changes during development and is modulated by polysialic acid

We have used monolayers of control 3T3 cells and 3T3 cells transfected with a cDNA encoding human N-CAM as a culture substrate for embryonic chick retinal ganglion cells (RGCs). At embryonic day 6 (E6), but not at E11, RGCs extended longer neurites on monolayers of N-CAM-transfected cells. This loss of RGC responsiveness was not associated with substantial changes in the level of N-CAM expression on RGC growth cones. The neurite outgrowth response from E6 RGCs could be inhibited by removal of N-CAM from the monolayer, by removal of alpha 2-8-linked polysialic acid from neuronal N-CAM, or by antibodies that bind exclusively to chick (neuronal) N-CAM. In contrast, the response was not dependent on neuronal beta 1 integrin function. These data provide substantive evidence for a homophilic binding mechanism directly mediating N-CAM-dependent neurite outgrowth, and suggest that changes in polysialic acid expression on neuronal N-CAM may modulate N-CAM-dependent axonal growth during development.     

Intercellular adhesion mediated by human muscle neural cell adhesion molecule: effects of alternative exon use

Mouse 3T3 fibroblasts were permanently transfected with cDNAs encoding isoforms of the neural cell adhesion molecule (N-CAM) present in human skeletal muscle and brain. Parental and transfected cells were then used in a range of adhesion assays. In the absence of external shear forces, transfection with cDNAs encoding either transmembrane or glycosylphosphatidylinositol (GPI)-linked N-CAM species significantly increased the intercellular adhesiveness of 3T3 cells in suspension. Transfection of a cDNA encoding a secreted N-CAM isoform was without effect on adhesion. Cells transfected with cDNAs containing or lacking the muscle-specific domain 1 sequence, a four-exon group spliced into the muscle but not the brain GPI-linked N-CAM species, were equally adhesive in the assays used. We also demonstrate that N-CAM-mediated intercellular adhesiveness is inhibited by 0.2 mg/ml heparin; but, at higher concentrations, reduced adhesion of parental cells was also seen. Coaggregation of fluorescently labeled and unlabeled cell populations was performed and measured by comparing their distribution within aggregates with distributions that assume nonspecific (random) aggregation. These studies demonstrate that random aggregation occurs between transfected cells expressing the transmembrane and GPI-linked N- CAM species and between parental cells and those expressing the secreted N-CAM isoform. Other combinations of these populations tested exhibited partial adhesive specificity, indicating homophilic binding between surface-bound N-CAM. Thus, the approach exploited here allows for a full analysis of the requirements, characteristics, and specificities of the adhesive behavior of individual N-CAM isoforms.     

Disruption of pioneer growth cone guidance in vivo by removal of glycosyl-phosphatidylinositol-anchored cell surface proteins.

Cell surface proteins anchored to membranes via covalently attached glycosyl-phosphatidylinositol (GPI) have been implicated in neuronal adhesion, promotion of neurite outgrowth and directed cell migration. Treatment of grasshopper embryos with bacterial phosphatidylinositol-specific phospholipase C (PI-PLC), an enzyme that cleaves the GPI anchor, often induced disruptions in the highly stereotyped migrations of peripheral pioneer growth cones and afferent neuron cell bodies. In distal limb regions of embryos treated with PI-PLC at early stages of pioneer axon outgrowth, growth cones lost their proximal orientation toward the central nervous system (CNS) and turned distally. Pioneer growth cones in treated limbs also failed to make a characteristic ventral turn along the trochanter-coxa (Tr-Cx) segment boundary, and instead continued to grow proximally across the boundary. Treatment at an earlier stage of development caused pre-axonogenesis Cx1 neurons to abandon their normal circumferential migration and reorient toward the CNS. None of these abnormal phenotypes were observed in limbs of untreated embryos or embryos exposed to other phospholipases that do not release GPI-anchored proteins. Incubation of embryos with PI-PLC effectively removed immunoreactivity for fasciclin I, a GPI-anchored protein expressed on a subset of neuronal surfaces. These results suggest that cell surface GPI-anchored proteins are involved in pioneer growth cone guidance and in pre-axonogenesis migration of neurons in the grasshopper limb bud in vivo.     

Cell adhesion molecules NgCAM and axonin-1 form heterodimers in the neuronal membrane and cooperate in neurite outgrowth promotion

The axonal surface glycoproteins neuronglia cell adhesion molecule (NgCAM) and axonin-1 promote cell-cell adhesion, neurite outgrowth and fasciculation, and are involved in growth cone guidance. A direct binding between NgCAM and axonin-1 has been demonstrated using isolated molecules conjugated to the surface of fluorescent microspheres. By expressing NgCAM and axonin-1 in myeloma cells and performing cell aggregation assays, we found that NgCAM and axonin-1 cannot bind when present on the surface of different cells. In contrast, the cocapping of axonin-1 upon antibody-induced capping of NgCAM on the surface of CV- 1 cells coexpressing NgCAM and axonin-1 and the selective chemical cross-linking of the two molecules in low density cultures of dorsal root ganglia neurons indicated a specific and direct binding of axonin- 1 and Ng-CAM in the plane of the same membrane. Suppression of the axonin-1 translation by antisense oligonucleotides prevented neurite outgrowth in dissociated dorsal root ganglia neurons cultured on an NgCAM substratum, indicating that neurite outgrowth on NgCAM substratum requires axonin-1. Based on these and previous results, which implicated NgCAM as the neuronal receptor involved in neurite outgrowth on NgCAM substratum, we concluded that neurite outgrowth on an NgCAM substratum depends on two essential interactions of growth cone NgCAM: a trans-interaction with substratum NgCAM and a cis-interaction with axonin-1 residing in the same growth cone membrane.     

Fasciclin III: a novel homophilic adhesion molecule in Drosophila

Drosophila fasciclin III is an integral membrane glycoprotein that is expressed on a subset of neurons and fasciculating axons in the developing CNS, as well as in several other tissues during development. Here we report on the isolation of a full-length cDNA encoding an 80 kd form of fasciclin III. We have used this cDNA, under heat shock control, to transfect the relatively nonadhesive Drosophila S2 cell line. Examination of these transfected cells indicates that fasciclin III is capable of mediating adhesion in a homophilic, Ca2+-independent manner. Sequence analysis reveals that fasciclin III encodes a transmembrane protein with no significant homology to any known protein, including the previously characterized families of vertebrate cell adhesion molecules. The distribution of this adhesion molecule on subsets of fasciculating axons and growth cones during Drosophila development suggests that fasciclin III plays a role in growth cone guidance.     

Expression of two different isoforms of fasciclin II during postembryonic central nervous system remodeling in <Emphasis Type="Italic">Manduca sexta</Emphasis>

Insect metamorphosis serves as a useful model to investigate postembryonic development in the central nervous system, because the transformation between larval and adult life is accompanied by a remodeling of neural circuitry. Most changes are controlled by ecdysteroids, but activity-dependent mechanisms and cell surface signals also play a role. This immunocytochemical study investigates the expression patterns of two isoforms of the neural cell adhesion molecule, fasciclin II (FasII), during postembryonic ventral nerve cord remodeling in the moth, Manduca sexta. Both the expression of the glycosyl-phosphatidylinositol (GPI)-linked isoform and the transmembrane isoform of Manduca FasII (TM-MFasII) are regulated in a stereotyped spatio-temporal pattern. TM-MFasII is expressed in a stage-specific manner in a subset of neurons. Subsets of central axons express high levels during outgrowth supporting a functional role for TM-FasII during pathfinding. Dendritic localization is not found at any stage of metamorphosis, suggesting no homophilic interactions of TM-MFasII during central synapse development. GPI-MFasII is expressed in a stage-specific manner, most likely only in glial cells. The larval and adult stages show almost no GPI-MFasII expression, whereas during pupal life, positive GPI-MFasII labeling is present around synaptotagmin-negative tracts or commissures, so that either homophilic stabilization of glial boundaries or heterophilic neuron-glial interactions possibly stabilize the axons within their tracts. GPI-MFasII expression is not co-localized with synaptotagmin-positive central terminals, rendering a role for synapse development unlikely. Neither isoform is expressed in all neurons of a specific class at any developmental stage, indicating that MFasII functions are restricted to specific subsets of neurons or to individual neurons. The support of the German Science Foundation (Du 331/4–1) and of Arizona State University to C.D. is greatly appreciated.     

Sensory neurons influence the expression of cell adhesion factors by cutaneous cells in vitro and in vivo

Dorsal root ganglion (DRG) neurons co-cultured with skin-derived fibroblast-like cells (FLCs) show a strong neurite outgrowth. However, when physical contact between FLCs and neurons is prevented with membrane inserts, the DRG neurons exhibit a low survival and a deficient neurite growth. This indicates that cell adhesion molecules influence neuronal survival and neurite growth in co-cultures. The aim of the present study is to find out if selected adhesion molecules are expressed by cultivated FLCs with and without nervous influences, and/or by normal and denervated whole skin. RT-PCR data show that cultured FLCs and denervated skin express L1, N-CAM, N-cadherin and ninjurin, but not neurofascin or TAG-1. However, cultured FLCs exposed to DRG homogenates and innervated skin express N-cadherin only. Following application of neutralizing L1-, N-cadherin- and ninjurin-antibodies (but not N-CAM-antibodies) in the culture medium the mean number of surviving neurons is decreased. Co-cultures incubated with L1-, N-cadherin- or ninjurin-antibodies all show significantly less neurite outgrowth compared to controls. In conclusion, the findings in this paper indicate (i) that FLCs cultured in vitro and denervated whole skin express the cell adhesion factors L1, N-CAM, N-cadherin and ninjurin, (ii) that FLCs treated with neural molecules and innervated whole skin express N-cadherin only, (iii) that L1, N-cadherin and ninjurin are important for DRG neurons co-cultured with FLCs in vitro in terms of survival and neurite extension and (iv) that there may exist subpopulations of DRG-neurons with different sensitivities for N-cadherin- and ninjurin-antibodies.     

Expression and release of phosphatidylinositol anchored cell surface molecules by a cell line derived from sensory neurons.

Early postnatal mouse dorsal root ganglion neurons were found to express several glycosylphosphatidylinositol-anchored (GPI) molecules from the immunoglobulin superfamily (neural cell adhesion molecule 120 kD isoform, F3, Thy1) whose expression is developmentally regulated. A hybrid cell line (ND26), made by fusing postmitotic rat dorsal root ganglion (DRG) neurons with the mouse neuroblastoma N18Tg2, could be induced to differentiate by manipulating the composition of the culture medium and expressed similar GPI molecules to DRG neurons. We used this model system to investigate the metabolism of GPI-anchored molecules. We found that neural cell adhesion molecule 120 Kd isoform expression decreased upon differentiation, whereas the level of F3 and Thy1 increased, suggesting a role in neurite outgrowth processes. The ratio of molecules cleavable by exogenous phosphatidylinositol phospholipase C (PI-PLC) was similar for all the GPI-anchored molecules, which could mean that cell-specific modifications of the basic anchoring structure determine the level of potentially releasable molecules. Measurements of spontaneous release indicated that this reflected the overall level of expression of these molecules by the ND26 cell line. Finally, we observed an effect of dibutyryl cAMP on the level of expression of F3 and Thy1 but not of N-CAM. However, we could not detect any significant effect of nerve growth factor (NGF) either on the level of expression or on the amount of spontaneously released molecules.     

A neuronal inhibitory domain in the N-terminal half of agrin.

Agrin is required for appropriate pre- and postsynaptic differentiation of neuromuscular junctions. While agrin's ability to orchestrate postsynaptic differentiation is well documented, more recent experiments have suggested that agrin is also a "stop signal" for the presynaptic neuron, and that agrin has actions on neurons in the CNS. To elucidate the neuronal activities of agrin and to define the receptor(s) responsible for these functions, we have examined adhesions of neurons and their neurite-outgrowth responses to purified agrin in vitro. We find that both full-length agrin and the C-terminal 95 kDa of agrin (agrin c95), which is sufficient to induce postsynaptic differentiation, are adhesive for chick ciliary ganglion (CG) and forebrain neurons. Consistent with previous findings, our results show that N-CAM binds to full-length agrin, and suggest that alpha-dystroglycan is a neuronal receptor for agrin c95. In neurite outgrowth assays, full-length agrin inhibited both laminin- and N-cadherin-induced neurite growth from CG neurons. The N-terminal 150 kDa fragment of agrin, but not agrin c95, inhibited neurite outgrowth, indicating that domains in the N-terminal portion of agrin are sufficient for this function. Adhesion assays using protein-coated beads and agrin-expressing cells revealed differential interactions of agrin with members of the immunoglobulin superfamily of cell adhesion molecules. However, none of these, including N-CAM, appeared to be critical for neuronal adhesion. In summary, our results suggest that the N-terminal half of agrin is involved in agrin's ability to inhibit neurite outgrowth. Our results further suggest that neither alpha-dystroglycan nor N-CAM, two known binding proteins for agrin, mediate this effect.     

Neurite Fasciculation Mediated by Complexes of Axonin-1 and Ng Cell Adhesion Molecule

Neural cell adhesion molecules composed of immunoglobulin and fibronectin type III-like domains have been implicated in cell adhesion, neurite outgrowth, and fasciculation. Axonin-1 and Ng cell adhesion molecule (NgCAM), two molecules with predominantly axonal expression exhibit homophilic interactions across the extracellular space (axonin- 1/axonin-1 and NgCAM/NgCAM) and a heterophilic interaction (axonin-1–NgCAM) that occurs exclusively in the plane of the same membrane (cis-interaction). Using domain deletion mutants we localized the NgCAM homophilic binding in the Ig domains 1-4 whereas heterophilic binding to axonin-1 was localized in the Ig domains 2-4 and the third FnIII domain. The NgCAM–NgCAM interaction could be established simultaneously with the axonin-1–NgCAM interaction. In contrast, the axonin-1–NgCAM interaction excluded axonin-1/axonin-1 binding. These results and the examination of the coclustering of axonin-1 and NgCAM at cell contacts, suggest that intercellular contact is mediated by a symmetric axonin-1₂/NgCAM₂ tetramer, in which homophilic NgCAM binding across the extracellular space occurs simultaneously with a cis-heterophilic interaction of axonin-1 and NgCAM. The enhanced neurite fasciculation after overexpression of NgCAM by adenoviral vectors indicates that NgCAM is the limiting component for the formation of the axonin-1₂/NgCAM₂ complexes and, thus, neurite fasciculation in DRG neurons.