Growth cones contain a dynamic population of neurofilament subunits

Neurofilaments (NFs) are classically considered to transport in a primarily anterograde direction along axons, and to undergo bulk degradation within the synapse or growth cone (GC). We compared overall NF protein distribution with that of newly expressed NF subunits within NB2a/d1 cells by transfection with a construct encoding green fluorescent protein (GFP) conjugated NF-M subunits. GCs lacked phosphorylated NF epitopes, and steady-state levels of non-phosphosphorylated NF subunits within GC were markedly reduced compared to those of neurite shaft as indicated by conventional immunofluorescence. However, GCs contained significant levels of GFP-tagged subunits in the form of punctate or short filamentous structures that in some cases exceeded that visualized along the shaft itself, suggesting that GCs contained a relatively higher concentration of newly synthesized subunits. GFP-tagged NF subunits within GCs co-localized with non-phosphorylated NF immunoreactivity. GFP-tagged subunits were observed within GC filopodia in which steady-state levels of NF subunits were too low to be detected by conventional immunofluorescence. Selective localization of fluorescein versus rhodamine fluorescene was observed within GCs following expression of NF-M conjugated to DsRed1-E5, which shifts from fluorescein to rhodamine fluorescence within hours after expression; axonal shafts contained a more even distribution of fluorescein and rhodamine fluorescence, further indicating that GCs contained relatively higher levels of the most-recently expressed subunits. GFP-tagged structures were rapidly extracted from GCs under conditions that preserved axonal structures. These short filamentous and punctate structures underwent rapid bi-directional movement within GCs. Movement of GFP-tagged structures within GCs ceased following application of nocodazole, cytochalasin B, and the kinase inhibitor olomoucine, indicating that their motility was dependent upon microtubules and actin and, moreover, was due to active transport rather than simple diffusion. Treatment with the protease inhibitor calpeptin increased overall NF subunits, but increased those within the GC to a greater extent than those along the shaft, indicating that subunits in the GC undergo more rapid turnover than do those within the shaft. Some GCs contained coiled aggregates of GFP-tagged NFs that appeared to be contiguous with axonal NFs. NFs extended from these aggregates into the advancing GC as axonal neurites elongated. These data are consistent with the presence of a population of dynamic NF subunits within GCs that is apparently capable of participating in regional filament formation during axonal elongation, and support the notion that NF polymerization and transport need not necessarily occur in a uniform proximal-distal manner.     

Tau inhibits anterograde axonal transport and perturbs stability in growing axonal neurites in part by displacing kinesin cargo: neurofilaments attenuate tau-mediated neurite instability

Overexpression of tau compromises axonal transport and induces retraction of growing neurites. We tested the hypothesis that increased stability provided by neurofilaments (NFs) may prevent axonal retraction. NB2a/d1 cells were differentiated for 3 days, at which time phosphorylated NFs appear and for 14 days, which induces continued neurite elongation and further phospho-NF accumulation. Cultures were transfected with a construct that expresses full-length, 4-repeat tau. Consistent with prior studies, overexpression of tau induced retraction of day three axonal neurites even following treatment with the microtubule-stabilizing drug taxol. Axonal neurites of day 14 cells were more resistant to tau-mediated retraction. To test whether or not this resistance was derived from their additional NF content, day 3 cultures were co-transfected with constructs expressing tau and NF-M (which increases overall axonal NFs). Overexpression of NF-M attenuated tau-mediated retraction of day 3 axonal neurites. By contrast, co-transfection with constructs expressing tau and vimentin (which increases axonal neurites length) did not attenuate tau-mediated neurite retraction. Co-precipitation experiments indicate that tau is a cargo of kinesin, and that tau overexpression may displace other kinesin-based cargo, including both critical cytoskeletal proteins and organelles. However, cultures simultaneously transfected with constructs expressing NF-M and tau, the level of examined vesicles was maintained. These collectively indicate that NFs stabilize developing axonal neurites and can counteract the destabilizing force resulting from overexpression of tau, and underscore that the development and stabilization of axonal neurites is dependent upon a balance of cytoskeletal elements.     

Regulation of the transition from vimentin to neurofilaments during neuronal differentiation

Vimentin (Vm) is initially expressed by nearly all neuronal precursors in vivo, and is replaced by neurofilaments (NFs) shortly after the immature neurons become post-mitotic. Both Vm and NFs can be transiently detected within the same neurite, and Vm is essential for neuritogenesis at least in culture. How neurons effect the orderly transition from expression of Vm as their predominant intermediate filament to NFs remains unclear. We examined this phenomenon within growing axonal neurites of NB2a/d1 cells. Transfection of cells with a construct expressing Vm conjugated to green fluorescent protein confirmed that axonal transport machinery for Vm persisted following the developmental decrease in Vm, but that the amount undergoing transport decreased in parallel to the observed developmental increase in NF transport. Immunoprecipitation from pulse-chase radiolabeled cells demonstrated transient co-precipitation of newly synthesized NF-H with Vm, followed by increasing co-precipitation with NF-L. Immunofluorescent and immuno-electron microscopic analyses demonstrated that some NF and Vm subunits were incorporated into the same filamentous profiles, but that Vm was excluded from the longitudinally-oriented "bundle" of closely-apposed NFs that accumulates within developing axons and is known to undergo slower turnover than individual NFs. These data collectively suggest that developing neurons are able to replace their Vm-rich cytoskeleton with one rich in NFs simply by down-regulation of Vm expression and upregulation of NFs, coupled with turnover of existing Vm filaments and Vm-NF heteropolymers.     

Transient neuritogenesis in NB2a/d1 neuroblastoma cells induced by glial-derived protease inhibitors

The initial outgrowth of neuritogenesis in mouse NB2a/d1 neuroblastoma cells may be regulated by thrombin or a thrombin-like protease, present either in serum or adsorbed to the plasma membrane, since neuritogenesis is induced by serum deprivation and treatment with the specific thrombin inhibitor, hirudin (Shea et al., 1991, J. Neurochem., 56:842). Cultured astroglial cells secrete factors that promote neuritogenesis, including protease inhibitors active against thrombin, leading to suggestions that the inhibition of specific neuronal surface proteases by the surrounding glial environment may represent an initial step in axonal outgrowth in situ. To examine the relative importance of glial-derived protease inhibitory activities on neurine outgrowth, we tested the neurite promoting effect of glial-conditioned medium (GCM) on NB2a/d1 cells. Like serum deprivation and hirudin treatment, GCM induced neurite outgrowth within 4 hr. Exogenous thrombin inhibited the effect of GCM, and cell-free enzyme assays confirmed the presence of thrombin-inhibitory activity in GCM, suggesting that GCM induces neuritogenesis by inhibition of a thrombin-like protease. Unlike neurites induced by serum removal or hirudin addition, which are rapidly resorbed following serum replenishment or hirudin depletion, however, GCM-induced neurites continued to elongate after GCM removal. Furthermore, cultures treated simultaneously with GCM and thrombin exhibited delayed outgrowth of neurites following GCM removal which were insensitive to further thrombin treatment. These findings indicate that the initial elaboration of neurites can be mediated by glial-derived protease inhibitor(s) active against a thrombin-like protease, but indicate the requirement of additional glial-derived factors for the maintenance and continued elaboration of these neurites.     

Regulation of neuronal migration and neuritogenesis by distinct surface proteases. Relative contribution of plasmin and a thrombin-like protease.

The relative contribution of two neuronal surface proteases, plasmin and a protease with thrombin-like specificity, on NB2a/dl neuroblastoma migration and neuritogenesis were examined. Exogenous plasmin induced cell body rounding and increased cell migration, but did not prevent or reverse neurite outgrowth. Inhibition of endogenous plasmin by its specific inhibitor, aprotinin, suppressed migration but did not induce neuritogenesis. Removal or inhibition of the thrombin-like protease by serum deprivation or hirudin addition, respectively, induced neurite outgrowth, as shown in our previous studies, but did not suppress migration. By contrast, trypsin induced simultaneous cell rounding and neurite retraction. These findings indicated that plasmin may regulate cell migration, while the thrombin-like protease may regulate facets of neurite outgrowth. Although unable to induce de novo neuritogenesis, plasmin inhibition potentiated the otherwise transient neurites induced by simultaneous inhibition of the thrombin-like protease. Since cultured neuronal cells migrate primarily in the direction of newly elaborated neurites, this finding is interpreted to indicate that cessation of neuronal migration by plasmin inhibition enhances net neurite outgrowth by inhibition of the putative thrombin-like protease.     

Multiple Proteases Regulate Neurite Outgrowth in NB2a/dl Neuroblastoma Cells

Mouse NB2a/dl neuroblastoma cells elaborate axonal neurites in response to various chemical treatments including dibutyryl cyclic AMP and serum deprivation. Hirudin, a specific inhibitor of thrombin, initiated neurite outgrowth in NB2a/dl cells cultured in the presence of serum; however, these neurites typically retracted within 24 h. The cysteine protease inhibitors leupeptin and N-acetyl-leucyl-leucyl-norleucinal (CI; preferential inhibitor of micromolar calpain but also inhibits millimolar calpain) at 10(-6) M considerably enhanced neurite outgrowth induced by serum deprivation, but could not induce neuritogenesis in the presence of serum. A third cysteine protease inhibitor, N-acetyl-leucyl-leucyl-methional (CII; preferential inhibitor of millimolar calpain but also inhibits micromolar calpain), had no detectable effects by itself. Cells treated simultaneously with hirudin and either leupeptin, CI, or CII elaborated stable neurites in the presence of serum. Cell-free enzyme assays demonstrated that hirudin inhibited thrombin but not calpain, CI and CII inhibited calpain but not thrombin, and leupeptin inhibited both proteases. These results imply that distinct proteolytic events, possibly involving more than one protease, regulate the initiation and subsequent elongation and stabilization of axonal neurites. Since the addition of exogenous thrombin or calpain to serum-free medium did not modify neurite outgrowth, the proteolytic events affected by these inhibitors may be intracellular or involve proteases distinct from thrombin or calpain.     

Alterations in dynamics of microtubule assembly during axonal neuritogenesis in NB2a/d1 cells

During dibutyryl cyclic AMP (dbcAMP)-mediated differentiation, axonal neurites elaborated by mouse NB2a/d1 neuroblastoma cells are initially colchicine-labile but attain colchicine-stability after 7 days. To examine whether or not differences in tubulin subunit turnover could account for the development of colchicine-stability, anti-tubulin antibodies were delivered into NB2a/d1 cells at various times during dbcAMP-mediated neurite outgrowth. These antibodies prevented initial neurite elaboration, and induced neurite retraction in cells treated with dbcAMP for up to 3 days, but did not induce neurite retraction for cells treated for 7 days. We conclude that a less dynamic, more slowly-turning over population of microtubules develops within neurites of cells treated with dbcAMP for 7 days.     

Distinct roles of PKC isoforms in NCAM-mediated neurite outgrowth

The role of protein kinase C (PKC) isoforms in the neural cell adhesion molecule (NCAM)-mediated neurite outgrowth was tested using a co-culture system consisting of fibroblasts with or without NCAM expression upon which either primary cerebellar granular neurones (CGN) or pheochromocytoma (PC12-E2) cells were grown. The latter transiently expressed various PKC isoforms and domains derived from selected PKCs. PKC inhibitors of various specificity inhibited NCAM-stimulated neuritogenesis from CGN, indicating that PKC is involved in this process. Moreover, stimulation by the NCAM-mimetic peptide, C3d, elicited phosphorylation of PKC in CGN. Expression of kinase-deficient forms of PKCalpha, betaI and betaII blocked NCAM-mediated neurite extension, but had no effect on nerve growth factor (NGF)-mediated neurite outgrowth. Expression of two PKCepsilon constructs: (i) a fragment from PKCepsilon encompassing the pseudosubstrate, the C1a domain (including the actin-binding site, ABS), and parts of the V3 region, or (ii) the PKCepsilon-specific ABS blocked NCAM-mediated neurite extension in both cases. These two constructs also partially inhibited NGF-stimulated neuritogenesis indicating that PKCepsilon is a positive regulator of both NCAM- and NGF-mediated differentiation. We suggest that PKCepsilon is a common downstream mediator for several neuritogenic factors, whereas one or more conventional PKCs are specifically involved in NCAM-stimulated neurite outgrowth.     

Regulation of neurofilament axonal transport by phosphorylation in optic axons in situ

Axonal transport of neurofilament (NFs) is considered to be regulated by phosphorylation. While existing evidence for this hypothesis is compelling, supportive studies have been largely restricted to correlative evidence and/or experimental systems involving mutants. We tested this hypothesis in retinal ganglion cells of normal mice in situ by comparing subunit transport with regional phosphorylation state coupled with inhibition of phosphatases. NF subunits were radiolabeled by intravitreal injection of 35S-methionine. NF axonal transport was monitored by following the location of the peak of radiolabeled subunits immunoprecipitated from 9x1.1 mm segments of optic axons. An abrupt decline transport rate was observed between days 1 and 6, which corresponded to translocation of the peak of radiolabeled subunits from axonal segment 2 into segment 3. Notably, this is far downstream from the only caliber increase of optic axons at 150 mu from the retina. Immunoblot analysis demonstrated a unique threefold increase between segments 2 and 3 in levels of a "late-appearing" C-terminal NF-H phospho-epitope (RT97). Intravitreal injection of the phosphatase inhibitor okadaic acid increased RT97 immunoreactivity within retinas and proximal axons, and markedly decreased NF transport rate out of retinas and proximal axons. These findings provide in situ experimental evidence for regulation of NF transport by site-specific phosphorylation.     

Neurofascin induces neurites by heterophilic interactions with axonal NrCAM while NrCAM requires F11 on the axonal surface to extend neurites

Neurofascin and NrCAM are two axon-associated transmembrane glycoproteins belonging to the L1 subgroup of the Ig superfamily. In this study, we have analyzed the interaction of both proteins using neurite outgrowth and binding assays. A neurofascin-Fc chimera was found to stimulate the outgrowth of tectal cells when immobilized on an inert surface but not as a soluble form using polylysine as substrate. Antibody blocking experiments demonstrate that neurite extension on immobilized neurofascin is mediated by NrCAM on the axonal surface. Under the reverse experimental conditions where NrCAM induces neurite extension, F11, and not neurofascin, serves as axonal receptor. Binding studies using transfected COS7 cells and immunoprecipitations reveal a direct interaction between neurofascin and NrCAM. This binding activity was mapped to the Ig domains within neurofascin. The neurofascin-NrCAM binding can be modulated by alternative splicing of specific stretches within neurofascin. These studies indicate that heterophilic interactions between Ig-like proteins implicated in axonal extension underlie a regulation by the neuron.     

Dynein mediates retrograde neurofilament transport within axons and anterograde delivery of NFs from perikarya into axons: regulation by multiple phosphorylation events

We examined the respective roles of dynein and kinesin in axonal transport of neurofilaments (NFs). Differentiated NB2a/d1 cells were transfected with green fluorescent protein-NF-M (GFP-M) and dynein function was inhibited by co-transfection with a construct expressing myc-tagged dynamitin, or by intracellular delivery of purified dynamitin and two antibodies against dynein's cargo domain. Monitoring of the bulk distribution of GFP signal within axonal neurites, recovery of GFP signal within photobleached regions, and real-time monitoring of individual NFs/punctate structures each revealed that pertubation of dynein function inhibited retrograde transport and accelerated anterograde, confirming that dynein mediated retrograde axonal transport, while intracellular delivery of two anti-kinesin antibodies selectively inhibited NF anterograde transport. In addition, dynamitin overexpression inhibited the initial translocation of newly-expressed NFs out of perikarya and into neurites, indicating that dynein participated in the initial anterograde delivery of NFs into neurites. Delivery of NFs to the axon hillock inner plasma membrane surface, and their subsequent translocation into neurites, was also prevented by vinblastine-mediated inhibition of microtubule assembly. These data collectively suggest that some NFs enter axons as cargo of microtubues that are themselves undergoing transport into axons via dynein-mediated interactions with the actin cortex and/or larger microtubules. C-terminal NF phosphorylation regulates motor association, since anti-dynein selectively coprecipitated extensively phosphorylated NFs, while anti-kinesin selectively coprecipitated less phosphorylated NFs. In addition, however, the MAP kinase inhibitor PD98059 also inhibited transport of a constitutively-phosphorylated NF construct, indicating that one or more additional, non-NF phosphorylation events also regulated NF association with dynein or kinesin.     

Phospho-dependent association of neurofilament proteins with kinesin in situ

Recent studies demonstrate co-localization of kinesin with neurofilament (NF) subunits in culture and suggest that kinesin participates in NF subunit distribution. We sought to determine whether kinesin was also associated with NF subunits in situ. Axonal transport of NF subunits in mouse optic nerve was perturbed by the microtubule (MT)-depolymerizing drug vinblastine, indicating that NF transport was dependent upon MT dynamics. Kinesin co-precipitated during immunoprecipitation of NF subunits from optic nerve. The association of NFs and kinesin was regulated by NF phosphorylation, since (1) NF subunits bearing developmentally delayed phospho-epitopes did not co-purify in a microtubule motor preparation from CNS while less phosphorylated forms did; (2) subunits bearing these phospho-epitopes were selectively not co-precipitated with kinesin; and (3) phosphorylation under cell-free conditions diminished the association of NF subunits with kinesin. The nature and extent of this association was further examined by intravitreal injection of (35)S-methionine and monitoring NF subunit transport along optic axons. As previously described by several laboratories, the wave of NF subunits underwent a progressive broadening during continued transport. The front, but not the trail, of this broadening wave of NF subunits was co-precipitated with kinesin, indicating that (1) the fastest-moving NFs were associated with kinesin, and (2) that dissociation from kinesin may foster trailing of NF subunits during continued transport. These data suggest that kinesin participates in NF axonal transport either by directly translocating NFs and/or by linking NFs to transporting MTs. Both Triton-soluble as well as cytoskeleton-associated NF subunits were co-precipitated with kinesin; these data are considered in terms of the form(s) in which NF subunits undergo axonal transport.     

The single neurofilament subunit of the lamprey forms filaments and regulates axonal caliber and neuronal size in vivo

Neurofilaments (NFs) are composed of a heteropolymer of three related subunits in mammalian neurons, where they are a major component of the cytoskeleton in large neurons and are thought to regulate axonal diameter. NFs in the lamprey, while ultrastructurally and functionally indistinguishable from mammalian NFs, are polymers of a single subunit protein, NF180. In this study, we use the simplicity of lamprey NFs and the accessibility of the lamprey central nervous system (CNS) to examine the effects of overproducing NFs in an identified giant neuron in vivo, and thus to elucidate the role of NFs in regulating neuronal size and axonal caliber in the vertebrate CNS. We show that overexpression of NF180 tagged with a variant of Green Fluorescent Protein (EYFP) in identified lamprey neurons (ABCs) and in human neuroblastoma (NB2a) cells results in the assembly of exogenous NF180 into ultrastructurally normal NFs that are tightly packed and unphosphorylated. These accumulate in the somata of NB2a cells and produce somatic swelling by 3 days post-transfection. NF180 overexpression in lamprey ABCs in vivo causes exogenous NFs to accumulate in ABC axons, somata, and dendrites, and induces a significant increase in axonal diameter without increasing axonal NF packing density. Overexpression of EYFP alone has none of these effects. We conclude that NF180 normally plays a critical role in determining axonal caliber in ABCs and may influence neuronal size in situations where NFs accumulate in the soma, such as after axonal injury.     

Microtubule motors,phosphorylation and axonal transport of neurofilaments

The recent demonstration that the axonal transport motors kinesin and dynein participate in axonal transport of neurofilaments (NFs), and that the association of NFs with these motors is regulated by phosphorylation provides new insight into several aspects of axonal transport and NF biology. This review juxtaposes older and more recent findings on NF dynamics, and speculates on the organization of axonal NFs as suggested by real-time analyses of NF transport.     

The role of stretching in slow axonal transport

Axonal stretching is linked to rapid rates of axonal elongation. Yet the impact of stretching on elongation and slow axonal transport is unclear. Here, we develop a mathematical model of slow axonal transport that incorporates the rate of axonal elongation, protein half-life, protein density, adhesion strength, and axonal viscosity to quantify the effects of axonal stretching. We find that under conditions where the axon (or nerve) is free of a substrate and lengthens at rapid rates (>4 mm day⁻¹), stretching can account for almost 50% of total anterograde axonal transport. These results suggest that it is possible to accelerate elongation and transport simultaneously by increasing either the axon's susceptibility to stretching or the forces that induce stretching. To our knowledge, this work is the first to incorporate the effects of stretching in a model of slow axonal transport. It has relevance to our understanding of neurite outgrowth during development and peripheral nerve regeneration after trauma, and hence to the development of treatments for spinal cord injury.     

Neurite formation by neurons derived from adult rat hippocampal progenitor cells is susceptible to myelin inhibition

Myelin-associated inhibitors expressed following injury to the adult central nervous system (CNS) induce growth cone collapse and retraction of the axonal cytoskeleton. Myelin-associated glycoprotein (MAG) is a bi-functional molecule that promotes neuritogenesis in some immature neurons during development then becomes inhibitory to neurite outgrowth as neurons mature. Progress is being made towards the elucidation of the downstream events that regulate myelin inhibition of regeneration in neuronal populations. However it is not known how adult-derived neural stem cells or progenitors respond to myelin during neuronal differentiation and neuritogenesis. Here we examine the effect of MAG on neurons derived from an adult rat hippocampal progenitor cell line (AHPCs). We show that, unlike their developmental counterparts, AHPC-derived neurons are susceptible to MAG inhibition of neuritogenesis during differentiation and display a 57% reduction in neurite outgrowth when compared with controls. We demonstrate that this effect can be overcome (by up to 69%) by activation of the neurotrophin, cyclic AMP and protein kinase A pathways or by Rho-kinase suppression. We also demonstrate that combination of these factors enhanced neurite outgrowth from differentiating neurons in the presence of MAG. This work provides important information for the successful generation of new neurons from adult neural stem cell populations within compromised adult circuitry and is thus directly relevant to endogenous repair and regeneration of the adult CNS.     

Glycosylphosphatidylinositol anchored recognition molecules that function in axonal fasciculation, growth and guidance in the nervous system.

A large number of glycoproteins in the central nervous system are attached to the cell membrane via covalent linkage to glycosylphosphatidylinositol (GPI). Many of them, including the drosophila fasciclin 1 as well as the mammalian glycoproteins Thy-1, TAG1, N-CAM and F11,F3, contactin are members of the immunoglobulin gene superfamily. These and other GPI-linked molecules have been implicated in key developmental events including selective axonal fasciculation and highly specific growth to and innervation of target tissues. In model systems fasciclin 1, TAG1 and N-CAM have been shown to be capable of mediating cell-cell adhesion via a homophilic binding mechanism confirming their operational classification as cell adhesion molecules (CAMs). However, of these molecules, only N-CAM has been shown to mediate a complex response (neurite outgrowth) via a homophilic binding mechanism. Whether the other molecules in this family mediate biological responses by binding to themselves and/or other molecules remains to be determined. Studies on N-CAM provide an ideal model system for understanding the function of GPI anchors since alternative splicing of the NCAM gene generates both lipid-linked and transmembrane N-CAM isoforms. Recent studies have shown that neurons can recognise and respond (by increased neurite outgrowth) to both lipid-linked and transmembrane N-CAM isoforms expressed on the surface of non-neuronal cells following transfection with appropriate cDNAs. The major determinant of neuronal responsiveness was the level of N-CAM expression rather than the isoform type. Neurite outgrowth in response to transfected N-CAM is mediated by transmembrane N-CAM isoforms expressed by neurons and this involves the activation of classical second messenger pathways in the neurons. One possibility is that GPI anchors are utilised when a cell has simply to provide recognition or positional information to a second cell whereas transmembrane molecules might be required for cells that actively respond to such information. The hypothesis is compatible with all the known information on N-CAM expression and function and may be extended to other adhesive events.     

Identification of neurite outgrowth-promoting domains of neuroglycan C, a brain-specific chondroitin sulfate proteoglycan, and involvement of phosphatidylinositol 3-kinase and protein kinase C signaling pathways in neuritogenesis

Neuroglycan C (NGC) is a transmembrane-type chondroitin sulfate proteoglycan that is exclusively expressed in the central nervous system. We report that the recombinant ectodomain of NGC core protein enhances neurite outgrowth from rat neocortical neurons in culture. Both protein kinase C (PKC) inhibitors and phosphatidylinositol 3-kinase (PI3K) inhibitors attenuated the NGC-mediated neurite outgrowth in a dose-dependent manner, suggesting that NGC promotes neurite outgrowth via PI3K and PKC pathways. The active sites of NGC for neurite outgrowth existed in the epidermal growth factor (EGF)-like domain and acidic amino acid (AA)-domain of the NGC ectodomain. The EGF-domain caused cells to extend preferentially one neurite from a soma, whereas the AA-domain caused several neurites to develop. The EGF-domain also enhanced neurite outgrowth from GABA-positive neurons, but the AA-domain did not. These results suggest that the EGF-domain and AA-domain have distinct functions in terms of neuritogenesis. From these findings, NGC can be considered to be involved in neuritogenesis in the developing central nervous system.