Multiple Regions of the NG2 Proteoglycan Inhibit Neurite Growth and Induce Growth Cone Collapse

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The Journal of Neuroscience, January 1, 2003, 23(1):175-186

Multiple Regions of the NG2 Proteoglycan Inhibit Neurite Growth and Induce Growth Cone Collapse
Yvonne M. Ughrin^*, Zhi Jiang Chen^*, and Joel M. Levine
Department of Neurobiology and Behavior, State University of New York at Stony Brook, Stony Brook, New York 11794

  ABSTRACT

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The NG2 chondroitin sulfate proteoglycan, an integral membrane proteoglycan, inhibits axon growth from cerebellar granuleneurons and dorsal root ganglia (DRG) neurons in vitro. The extracellulardomain of the NG2 core protein contains three subdomains: an N-terminalglobular domain (domain 1), a central extended domain that hasthe sites for glycosaminoglycan (GAG) attachment (domain 2), anda juxtamembrane domain (domain 3). Here, we used domain-specificfusion proteins and antibodies to map the inhibitory activitywithin the NG2 core protein. Fusion proteins encoding domain 1(D1-Fc) or domain 3 (D3-Fc) of NG2 inhibited axon growth fromcerebellar granule neurons when the proteins were substrate-bound.These proteins also induced growth cone collapse from newbornDRG neurons when added to the culture medium. Domain 2 only inhibitedaxon growth when the GAG chains were present. Neutralizing antibodiesdirected against domain 1 or 3 blocked completely the inhibitionfrom substrates coated with D1-Fc or D3-Fc. When the entire extracellulardomain of NG2 was used as a substrate, however, both neutralizingantibodies were needed to reverse completely the inhibition. WhenNG2 was expressed on the surface of HEK293 cells, the neutralizinganti-D1 antibody was sufficient to block the inhibition, whereasthe anti-D3 antibody had no effect. These results suggest thatdomains 1 and 3 of NG2 can inhibit neurite growth independently.These inhibitory domains may be differentially exposed dependingon whether NG2 is presented as an integral membrane protein oras a secreted protein associated with the extracellularmatrix.

Key words: regeneration; glial scars; chondroitin sulfate proteoglycan; spinal cord injury; NG2; growth cone collapse

  Introduction

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The developing and adult brain contains a diverse and complex array of proteoglycans (PGs; Herndon and Lander, 1990). Themolecular diversity of PGs arises from both the different polypeptidechains comprising the core proteins and the glycosaminoglycan(GAG) modifications of these core proteins. Proteoglycans varyin their cellular locations and are associated with cell surfaces,the extracellular matrix, and perineuronal nets (for review, seeBandtlow and Zimmermann, 2000; Hartmann and Maurer, 2001). Thecellular functions of PGs are as diverse as their structures.One of the most studied functions of PGs in the nervous systemis their ability to modulate axonal growth, guidance, and regeneration(Bovolenta and Fernaud-Espinosa, 2000). PGs can directly stimulateor inhibit axon growth, and some PGs act as necessary cofactorsthat modulate the responses to other guidance factors (Hu, 2001;Ronca et al., 2001). Proteoglycans are found at high levels inglial scars, where they are thought to contribute to the creationof an environment that prevents nerve regeneration (Asher et al.,2001).

One well characterized PG of the nervous system is the NG2 chondroitin sulfate proteoglycan (CSPG; Levine and Nishiyama, 1996).NG2 comprises a large, integral membrane PG with a core proteinof ~300 kDa and at least one covalently attached chondroitin sulfate(CS) GAG chain (Nishiyama et al., 1991; Stallcup and Dahlin-Huppe,2001). The large extracellular domain of the core protein canbe divided into three smaller domains; an N-terminal globulardomain, a central extended domain, and a juxtamembrane domain.Within the CNS, NG2 is found almost exclusively on the surfacesof developing and adult oligodendrocyte precursor cells (Levineet al., 2001). Elsewhere, NG2 is associated with developing chondrocytes,cardiomyocytes, pericytes, and several different human tumors(Levine and Nishiyama, 1996). Because NG2 can be secreted or shedfrom the cell surface, it also has the potential to become incorporatedinto the extracellular matrix (ECM) produced by these cell types(Nishiyama et al., 1995). NG2 interacts with a large number ofdifferent proteins including ECM molecules and growth factors(Burg et al., 1996; Goretzki et al., 1999). The binding sitesfor some of these ligands have been mapped to specific regionsof the NG2 core protein. For example, type VI collagen binds tothe central domain 2, and PDGF-AA and basic FGF (bFGF) bind toseparate sites in domains 2 and 3 of NG2 (Tillet et al., 1997;Goretzki et al., 1999). Thus, NG2 is constructed of distinct functionalmodules.

Purified preparations of NG2 and membrane-associated NG2 inhibit axon growth in vitro (Dou and Levine, 1994; Chen et al.,2002). Because levels of NG2 rapidly increase at sites of CNSinjury (Levine, 1994), this inhibitory property may be an importantnegative factor for CNS regeneration. The regions of the largecore protein performing these growth-inhibitory functions havenot yet been identified. Here, we have used a combination of domain-specificfusion proteins and monoclonal antibodies to map the growth-inhibitoryfunctions of NG2 to domains 1 and 3 of the core protein. Theseregions may be differentially exposed depending on whether NG2is presented as an integral membrane protein or as an extracellularfactor.

  Materials and Methods

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Reagents. Unless otherwise noted, all reagents were purchased from Sigma (St. Louis, MO). Plasmid DNA encoding for the extracellulardomain of L1 fused to an Fc tail was provided by V. Lemmon (CaseWestern Reserve University, Cleveland, OH), and plasmid Coll-1-pAG-CT,encoding a chick collapsin-1 myc/his fusion protein (Koppel andRaper, 1998), was a gift from J. Raper (University of Pennsylvania,Philadelphia, PA). Sprague Dawley rats were obtained from TaconicFarms (Germantown, NY) and maintained in the university animalhousing facility. All procedures involving animals were reviewedand approved by the local Institutional Animal Care and UseCommittee.

Construction of NG2 expression plasmids. cDNA fragments coding for domain 1 (D1, amino acids 30-640), domain 2 (D2, aminoacids 636-1591), domain 3 (D3, amino acids 1592-2222), and domains1 and 2 (D1,2, amino acids 30-1591) of NG2 were generated by PCRamplification (Expand high-fidelity PCR system; Roche MolecularBiochemicals, Indianapolis, IN) using a full-length rat NG2 cDNAas a template (pBSNG2, a gift from A. Nishiyama, University ofConnecticut, Storrs, CT). The primers used were as follows: forthe D1-Fc construct, 5' primer, nucleotides 157-186, 3' primer,nucleotides 1972-1989; for D2-Fc, 5' primer, nucleotides 1975-1993,3' primer 4825-4842; and for D3-Fc, 5' primer, nucleotides 4843-4859,3' primer, nucleotides 6723-6740. For D1,2-Fc, a 5' primer correspondingto nucleotides 157-186 and a 3' primer encompassing nucleotides4825-4842 were used. Restriction enzyme digestion sites were incorporatedinto each primer to facilitate cloning of the amplified fragmentsinto signal pIG plus mammalian expression vector (Novagen, Madison,WI). A control MUC18-Fc expression plasmid was also obtained fromNovagen. A cDNA encoding a myc/his fusion protein containing theentire extracellular domain (ECD) of NG2 was constructed in twosteps. First, PCR was used to generate a 1012 base pair fragmentencoding the region of NG2 from nucleotides 5636-6738. After gelpurification, this fragment was ligated into the XhoI and XbaIsites of pcDNA3-NG2 (Chen et al., 2002) to generate a cDNA encodingthe entire ECD without a transmembrane domain and a cytoplasmictail. An XbaI-BssHII fragment of this vector was ligated intopcDNA3.1 myc/hisB( $-$ ) (Invitrogen, San Diego, CA). A cDNA encodingonly D3, the transmembrane region and cytoplasmic domain of NG2,was constructed by digesting the D3-Fc expression plasmid withSpeI. This fragment, which contained part of the cytomegaloviruspromoter, the CD33 signal peptide, and the first half of D3, wasligated into a gel-purified fragment of SpeI-digested pcDNA3-NG2containing the entire NG2 coding region 3' to the SpeI site atnucleotide 6051 and much of the pcDNA3 backbone. The junctionsand reading frames of all constructs were verified by restrictionmapping and partial DNAsequencing.

Transfection and selection of stable lines. COS-1 and HEK293 cells were maintained in DMEM (Mediatech, Washington, DC) containing10% fetal bovine serum (FBS; JRH Biosciences, Lenexa, KS) at 37°Cand 10% CO₂. For transient transfection, the cells were grownto ~70% confluence on 100 mm tissue culture plates and transfectedusing LipofectAMINE (Invitrogen) according to the manufacturer'srecommendations. After 16-24 hr, the transfection media was replacedwith 5 ml of Optimem (Invitrogen), and the cells were grown for3 additional days before collecting the supernatants. Stable expressingcell lines were generated similarly and selected after growthin medium containing G418 (800 µg/ml;Invitrogen).

Protein purification. Fc fusion proteins were purified by passing serum-free conditioned media over protein A-Sepharose columns.After washing with PBS, bound proteins were eluted with 50 mMglycine, pH 1.9, and immediately neutralized with 0.1 volume of1 M Tris base. After overnight dialysis against PBS, protein concentrationswere determined using Micro BCA protein assay reagents (Pierce,Rockford, IL) with bovine serum albumin (BSA) as the standard.The 290 kDa soluble fragment corresponding to the ECD of NG2 waspurified from B49-conditioned serum-free media by ion exchangechromatography as described previously (Tillet et al., 1997).Two separate fractions of the ECD fragment were eluted from thecolumn at different salt concentrations, one that contained NG2with attached GAGs (0.55 M fraction) and another comprising theNG2 core protein without covalently attached GAGs (0.4 M fraction).The myc/his-tagged fusion protein was purified from conditionedmedium using a 1 ml HisTrap column (Amersham Biosciences, ArlingtonHeights,IL).

Enzymatic treatment of the NG2-Fc chimeras. Purified NG2 fragments were treated with protease-free chondroitinase (C'ase)ABC (0.01 U/2 µg of protein; obtained from Roche and SeikagakuKogyo Co., Tokyo, Japan) at 37°C for 1 hr in PBS. D2-Fc was incubatedwith keratanase (0.1 U/µg of protein; Seikagaku Kogyo) at 37°Cfor 1 hr in PBS, pH 7.4, containing 2 mM PMSF. An aliquot fromeach digestion mixture was assayed by Western blotting with rabbitanti-NG2antibodies.

Neurite outgrowth assay. Tissue culture substrates were prepared by coating 48-well tissue culture plates (Falcon; BectonDickinson, Mountain View, CA) with 25 µg/ml poly-L-lysine (PLL)overnight, followed by either 2.5 µg/ml L1-Fc alone or a mixtureof L1-Fc (2.5 µg/ml) and 0.5-60 nM Fc-fusion proteins for 3.5hr at 37°C. The protein-coated surfaces were washed with PBS andincubated in serum-containing medium before seeding with neurons.In the case when substrates were treated with antibodies, theprotein-coated surfaces were incubated with monoclonal antibodiesat 5 µg/ml for 1 hr at 37°C before seeding the neurons. Cerebellargranule neurons were partially purified from trypsin dissociatesof postnatal day 3-5 rat cerebella on discontinuous Percoll gradients(Hatten, 1985) and seeded onto protein-coated wells at 2 × 10⁴ cells per well in DMEM containing 10% FCS, 20 nM KCl, and 10ng/ml bFGF (Peprotech, Rocky Hill, NJ). After 24 hr in culture,the cells were washed in PBS and fixed in PBS containing 2%glutaraldehyde.

Digital images of the neurons were acquired using an Axiovert microscope (Zeiss, Thornwood, NY) equipped with a charge-coupleddevice camera (Hamamatsu) and Metamorph Imaging software (UniversalImaging Corp., West Chester, PA). The lengths of at least 50 neuriteswere measured for each condition. A neurite was defined as a processextending from the cell body by at least 16 µm (approximatelytwo cell diameters). In cases in which cells had more than oneneurite, only the longest neurite was measured. The mean neuritelength for each substrate condition was calculated and averagedacross experiments. The percentage of inhibition of neurite growthis defined as [1 $-$ (mean^expt/mean^control)] × 100, where mean^expt is the mean length under experimental conditions, and mean^control is the mean length of neurites grown on L1 alone for a givendata set. Multiple group comparisons were made by a two-tailedANOVA and Scheffé's post hoc tests (SuperANOVA; Abacus Concepts,Berkeley,CA).

Growth cone collapse assays. Dorsal root ganglia (DRG) were isolated from newborn (postnatal day 0) rats and dissociated asdescribed previously (Dou and Levine, 1995). The neurons wereplated at a density of 15 cells/mm² onto tissue culture wells that had been coated overnight with50 µg/ml PLL overnight at 37°C, followed by 10 µg/ml laminin for2.5 hr at 37°C. The cells were grown in DMEM containing 10% FBS,20 mM KCl, and 60 ng/ml NGF (a gift from Dr. L. Mendell, StateUniversity of New York at Stony Brook) for 7-8 hr before usingin the collapseassays.

For the collapse assays, serial dilutions of test proteins were prepared in tissue culture medium and warmed to 37°C. Mediumwas removed from the wells and immediately replaced with the testsolutions. After incubation at 37°C for 30 min, cultures werequickly washed once in PBS and fixed in 2% glutaraldehyde inPBS.

To quantitate the effects of the different soluble proteins on DRG growth cones, randomly selected fields of DRG neurons wereimaged as described above. Following the suggestion of Cox etal. (1990), a spread growth cone was defined as one having broadlamellipodia and numerous filopodia, whereas a collapsed growthcone had no lamellipodia and few, if any, filopodia. Growth conesthat were intermediate in appearance, i.e., small lamellipodiaand numerous small filopodia, were not scored because of the inherentambiguity in classifying them as either spread or collapsed inthis type of assay. Each experimental solution was tested in duplicatewells, and ~100 individual well isolated growth cones were scoredfrom each well. The percentage of collapsed growth cones was calculatedfrom the total number of growth cones scored. Data was normalizedto the mean percent collapse of control cultures across all experimentsto compare the dose-response curves of the different fusion proteins.Multiple group comparisons were made by a two-tailed ANOVA andScheffé's post hoc tests(SuperANOVA).

Membrane carpet assay. The membrane carpet assay was performed as described previously (Tuttle et al., 1995; Chen et al.,2002). For the antibody treatments, the cell membranes were mixedwith the purified antibodies at the indicated concentration andincubated on ice for 30 min, and the mixture was used to makethe membranecarpets.

Solid-phase ELISAs. ELISAs were performed to measure the amount of Fc fusion protein bound to tissue culture wells used inthe neurite outgrowth assays. Either PLL-coated wells were coatedwith Fc fusion proteins for 3.5 hr at 37°C (as in the neuriteexperiments), or the fusion proteins were added to the wells andthen dried under vacuum. Rabbit anti-NG2 (1:2500) and an alkalinephosphatase-conjugated goat anti-rabbit IgG secondary antibody(1:2500; Southern Biotechnology, Alabaster, AL) were used to detectthe amount of the NG2-Fc fusion proteins bound. After a 30 minincubation with the conjugated secondary antibody, wells werewashed three times and treated with p-nitrophenylphosphate at1 mg/ml in 10% diethanolamine. After 15 min at room temperature,the optical density of the wells at 405 nm was determined. Theamount bound after 3.5 hr of incubation was compared with theamount bound after vacuum drying, which was considered indicativeof the total amount of input protein. These assays demonstratedthat when used at 5 µg/ml (10-20 nM), between 80 and 100% of theinput Fc fusion proteins bound to the PLL-coatedsurfaces.

Solid-phase binding assays. Maxi-sorp 96-well plates (Nunc, Naperville, IL) were coated overnight with 2-20 µg/ml immunoaffinity-purifiedL1 (Dou and Levine, 1994) in PBS at 4°C. The surfaces were thenblocked by incubation with 1% BSA in Tris-buffered saline (TBS;50 mM Tris, pH 7.5, and 0.15 M NaCl) for 2 hr at 37°C. SolubleFc fusion proteins (4 or 40 nM) were diluted in TBS containing0.05% Tween 20 (TBST) and incubated with substrate-coated wellsfor 2 hr at 37°C. After three washes with TBST, the plates wereincubated with an HRP-conjugated anti-Fc antibody (1:10,000) for1 hr at 37°C. After three more washes, 50 µl of freshly prepared0.2 mg/ml o-phenylenediamine dihydrochloride in phosphate-citratebuffer was added to each well. After 1 hr at 37°C, the absorbanceat 490 nm was measured using a plate reader. Wells not coatedwith L1 were designated blanks, and the readings from these wellswere subtracted from the appropriate test wells to exclude nonspecificbinding of fusion proteins and antibodies to the surfaces. Asa positive control, the binding of NG2-Fc fusion proteins to wellscoated with 2 µg/ml collagen VI (Chemicon, Temecula, CA) was alsomeasured.

Production of monoclonal antibodies. Mice were immunized by intraperitoneal injection of 1 × 10⁷ 293-NG2 cells or 293-D3 cells three times at 1 week intervals.The mice were allowed to rest for 1 month after the third injectionand then were further immunized with a final boost. Fusion ofspleen cells with P3xAg8.653 myeloma cells was performed 4 d afterthe final boost. Tissue culture supernatants from wells with cellcolonies were screened by ELISA, using purified ECD-myc/his orD3-Fc as a target antigen. Positive clones were further screenedby immunofluorescence staining of 293-NG2 and 293-D3 cells. Thebinding specificity of the resulting antibodies was tested byELISA and immunoblot assays, using ECD-myc/his, D1-Fc, D2-Fc,and D3-Fc as targets. Positive clones were also screened for theirability to neutralize the neurite growth-inhibitory activity ofNG2 and NG2-derived fusion proteins using the neurite outgrowthassay and the membrane carpet assay described above. Three differentmonoclonal antibodies (mAbs) designated as 69, 132, and 147 wereobtained and selected for further study and analysis. mAb 69 isan IgG2a, whereas mAbs 132 and 147 are IgG1. Serum-free supernatantswere produced from each clone, and the antibodies were purifiedby affinity chromatography using protein G-Sepharose columns (AmershamBiosciences).

Immunofluorescence staining. The immunofluorescence staining methods were similar to those described previously (Levine andStallcup, 1987). The following antibodies were used: rabbit anti-NG2antibody (1:300; Levine and Card, 1987), monoclonal anti-NG2 antibody69 (anti-D1), D31.10 (anti-D2), 147 (anti-D3N), and 132 (anti-D3).All the monoclonal anti-NG2 antibodies were used at the concentrationof 1 µg/ml. Cyanine (CY3)-conjugated goat anti-mouse (JacksonImmunoResearch, West Grove, PA) and FITC-conjugated goat anti-rabbit(Southern Biotechnology; Fisher Scientific, Pittsburgh, PA) antibodieswere used as secondary antibodies. Cultures were examined usinga Zeiss Axioplan microscope equipped with fluorescence and differentialinterference contrast (DIC)optics.

Western blot analysis. Fc and myc/his NG2 fusion proteins were electrophoresed on either 6 or 6-15% gradient polyacrylamide-SDSgel reducing conditions and immunoblotted as described previously(Levine et al., 1998; Martin et al., 2001) using ECL reagents(Amersham Biosciences). Primary antibodies included a polyclonalanti-NG2 antibody (1:2000) and monoclonal anti-NG2 antibodies69, D31.10, 147, and 132. All the monoclonal anti-NG2 antibodieswere used at 1 µg/ml. For detection of the Fc epitope tag, weused an HRP-conjugated anti-human Fc antibody (1:25,000).

  Results

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Generation and characterization of NG2 fusion proteins

A schematic view of the domain structure of NG2 is shown in Figure 1A. To identify those regions of the large NG2 core proteinthat inhibit neurite outgrowth, we prepared Fc fusion proteinscontaining each of the three subdomains of the large ECD of NG2and a fourth Fc fusion protein containing domains 1 and 2 together.The Fc tail was fused to the C terminus of each protein. As acontrol for any effects of the Fc tail, we used a MUC18-Fc fusionprotein (Lehmann et al., 1989). We also prepared the entire ECDof NG2 fused at its C terminus to a myc epitope and six histidineresidues (ECD-myc/his). For some experiments, the ECD was purifiedbiochemically from serum-free medium conditioned by B49 cells(Tillet et al., 1997). Each of these soluble proteins was purifiedfrom conditioned medium by affinity chromatography as describedin Materials and Methods. Figure 1B shows a Coomassie brilliantblue-stained SDS gel of the fusion proteins after purification.Because fusion proteins containing domain 2 are modified withCS GAG chains, they are polydisperse in their molecular weightsand difficult to visualize in stained gels. After digestion withchondroitinase ABC, however, each of the CS GAG-containing fusionproteins electrophoresed as a single polypeptide. (The lower-molecularweight band seen in the lanes marked + is the chondroitinase enzyme.)The ECD-myc/his fusion protein also contained CS GAG chains butwas able to enter the 6% polyacrylamide gels used. Figure 1C showsthat each of the domain-specific Fc fusion proteins was detectedon immunoblots with polyclonal antibodies raised against nativeNG2 (left panel) and with anti-human Fc antibodies (right panel).As in the stained gel, treatment of domain 2-containing fusionproteins with C'ase reduced the size heterogeneity and increasedthe amount of the polypeptide band detected. Digestion with keratanasedid not alter the molecular weight of domain 2-containing fusionproteins (data not shown). The apparent molecular weights of thefusion proteins were generally 10-20% higher than the molecularweights predicted from the amino acid sequences; this variationcould be attributable to glycosylation, because each domain containspotential sites for the attachment of N-linked carbohydrates (Nishiyamaet al., 1991).

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Figure 1. Characterization of the NG2 proteins used in this study. A, Schematic diagrams showing the domain structure of NG2. The numbers in the top panel represent the amino acid residues that constitute the boundaries between domains 1-3. The positions of the Fc fusion proteins and the entire ECD are indicated by the thick bars. B, Coomassie brilliant blue-stained gels showing the composition of the NG2-Fc fusion proteins (left panel) and ECD-myc/his fusion proteins (right panel). C, Immunoblots demonstrating that each NG2-Fc protein is recognized by polyclonal antibodies against NG2 (left panel) and by a monoclonal antibody against human Fc (right panel). In both B and C, the proteins were electrophoresed on 6-15% gradient polyacrylamide gels. +, Samples that were treated with chondroitinase ABC before gel electrophoresis; $-$ , untreated samples. The far right lane in B is C'ase ABC alone. The arrows to the left indicate the mobility of molecular weight standards; from top to bottom, they are 182, 121, 86, and 69 kDa.

Fc fusion proteins inhibit neurite outgrowth in vitro

We used a neurite outgrowth assay (Dou and Levine, 1994) to measure the ability of different regions of the NG2 core proteinto inhibit neurite outgrowth from neonatal rat cerebellar granuleneurons. In this assay, neurite growth on surfaces coated withan L1-Fc fusion protein is compared with growth on surfaces coatedwith both L1- and NG2-containing fusion proteins. L1-Fc robustlypromoted the growth of cerebellar granule neurons and was maximallyeffective when used at 3.0-4.0 µg/ml (mean neurite length, 129± 6.0 µm; data not shown). Therefore, for the assays describedhere, we used L1-Fc at 2.5 µg/ml, a concentration that promoted~80-85% of the maximal neurite outgrowth obtainable. To confirmthat the NG2-containing fusion proteins bound to the L1-coatedsurfaces, we used an ELISA as described in Materials and Methods.Greater than 80% of the input Fc-fusion proteins bound to theL1-Fc-coated surfaces (data not shown). We have shown previouslythat the inclusion of NG2 in the coating mixtures did not interferesignificantly with the binding of L1 or laminin to tissue culturesurfaces (Dou and Levine, 1994). Although these data suggest thatNG2 and L1 bind independently to the PLL-coated surfaces, theydo not rule out a possible direct interaction between NG2 andL1. Other growth-inhibitory CSPGs bind to cell adhesion molecules,including L1, neural cell adhesion molecule, and TAG1 (Friedlanderet al., 1994; Milev et al., 1996). We determined, therefore, whetherthe NG2 fusion proteins bind to L1 directly using a solid-phasebinding assay as described in Materials and Methods. As shownin Figure 2A, there was little direct interaction between theNG2 fusion proteins and L1 when the fusion proteins were testedat either a concentration approximately equal to the EC₅₀ forinhibition of neurite extension (Table 1) or a 10-fold higherconcentration. Furthermore, the fusion proteins did not bind toL1-coated wells when L1 was used at concentrations as high as20 µg/ml (data not shown). Figure 2B shows control experimentsin which the binding of the fusion proteins to immobilized typeVI collagen was measured. In agreement with previous studies (Tilletet al., 1997), domain 2-containing fusion proteins bound to typeVI collagen. Domain 1-Fc also bound to type VI collagen but notas strongly as either D2-Fc or D1,2-Fc. This binding is mediatedby the NG2 domains and not the Fc tail, because a control fusionprotein, MUC18-Fc, did not bind to either L1 or collagen VI. Together,these data show that (1) NG2-Fc fusion proteins bind to the tissueculture substrates; (2) this binding is independent of the bindingof L1 to the surfaces; and (3) the fusion proteins retain at leastsome of their known biological properties (Tillet et al., 1997).

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Figure 2. NG2-Fc proteins do not interact directly with L1. Solid-phase binding of NG2-Fc fusion proteins to either L1 or collagen VI was performed as described in Materials and Methods. The indicated Fc fusion proteins were used at either 4 nM (filled bars) or 40.5 nM (hatched bars). Bound ligands were detected with a monoclonal antibody against the Fc tail. Values shown are mean ± SEM from two separate experiments comprising duplicate wells.


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Table 1. Growth-inhibitory activities of NG2 fusion proteins

We tested the ability of the NG2-Fc fusion proteins to inhibit L1-stimulated neurite growth from postnatal cerebellar granuleneurons over a range of concentrations. The ECD of NG2 and the4 Fc-fusion proteins derived from the ECD each inhibited neuritegrowth in a dose-dependent manner (Fig. 3A). Neurite lengths weresignificantly shorter (p < 0.001; ANOVA and Scheffé's post hoctest) compared with the L1 controls when the D1, D1,2, and D3fusion proteins were used at 4 nM or higher. In the case of D2-Fc,neurite lengths were statistically different from those on theL1-coated surface (p < 0.001; ANOVA and Scheffé's post hoc test)only when used at 20 nM or higher concentrations. Over the entirerange of concentrations, there were no statistically significantdifferences between the effectiveness of the four fusion proteinsand the ECD (p > 0.05; ANOVA and Scheffé's post hoc test). Forall the proteins tested, maximal inhibition of between 39 and51% was achieved at a 20 nM concentration (Table 1). This inhibitionof neurite extension was not attributable to the Fc tail on theseproteins, because surfaces coated with MUC18-Fc, a member of theIg superfamily, were not inhibitory for neurite growth. Thus,the inhibitory activity of the different NG2 fusion proteins isa specific function of the NG2 portion of these molecules.

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Figure 3. Multiple domains of NG2 inhibit L1-stimulated neurite outgrowth from cerebellar neurons. Neurite length on different surfaces was measured as described in Materials and Methods. A, The percentage of inhibition of neurite length (y-axis) for each substrate condition is plotted against the concentration of test protein (x-axis): D1-Fc (), D2-Fc ( $triangle$ ), D1,2-Fc ( $open circle$ ), D3-Fc ( $down-triangle$ ), ECD (), and MUC-Fc ( $diamond$ ). B, Effects of C'ase digestion. Domain 2-containing fusion proteins were treated with C'ase as described in Materials and Methods, and the effects of this digestion on the inhibition of neurite outgrowth was measured and analyzed as in A. The response to D2-Fc ( $triangle$ ) is reduced after treatment with C'ase ( $black-triangle$ ), whereas the response to D1,2-Fc ( $open circle$ ) is not changed after digestion (). C-K, Appearance of cerebellar neurons on the different substrates. All the proteins were used at 20 nM unless indicated otherwise. The substrates are as follows: C, L1-Fc alone or L1-Fc mixed with D, ECD (17 nM); E, MUC-Fc; F, D1-Fc; G, D2-Fc; H, C'ase-digested D2-Fc; I, D1,2-Fc; J, C'ase-digested D1,2-Fc; and K, D3-Fc. L1-Fc was used at 2.5 µg/ml throughout. Scale bar, 50 µm.

Because fusion proteins containing domain 2 have attached CS GAG chains, we evaluated the contribution of the GAGs to growthinhibition by treating the D1,2 and D2 fusion proteins with C'aseto remove the GAG chains. Removing the GAG chains from D1,2-Fchad no effect on the ability of the protein to inhibit neuriteoutgrowth (Fig. 3B). After removing the GAG chains from D2-Fc,however, the protein was less effective as an inhibitor of neuriteextension, and approximately fourfold to fivefold higher concentrationsof chondroitinase-treated D2-Fc were needed to achieve the sameextent of inhibition as without enzyme treatment. Figure 3C-Kshows examples of the neurons grown under some of the conditionstested. With the exception of shorter neurites, no morphologicaldifferences were noted across the various growth conditions used.These data demonstrate that two different regions of the NG2 coreprotein, domains 1 and 3, can inhibit axon growth. The polypeptidecore of domain 2 is inhibitory only when used at high concentrations.Although the CS GAG chains associated with domain 2 contributeto growth inhibition, they do not do so when domain 1 ispresent.

NG2 fusion proteins induce growth cone collapse

The assays used above measure growth inhibition after 24 hr exposure to the fusion proteins. The rapid effects of growth-inhibitorymolecules are often manifested as growth cone collapse. To determinewhether acute exposure to soluble fragments of NG2 can inducegrowth cone collapse, we measured the effects of adding the fusionproteins to cultures of newborn rat DRG neurons as described inMaterials and Methods. As shown in Figure 4A, our panel of NG2-derivedfusion proteins all induced the collapse of growth cones of postnatalday 0 rat DRG neurons when added in a soluble form. Under controlconditions, ~30% of all the growth cones analyzed were in a collapsedstate. This increased to ~50% when the fusion proteins were addedat their maximally effective concentrations (Table 1). Therewere no significant statistical differences among the effectsof the different NG2 fusion proteins; all of them were as effectiveas the entire ECD, and all were significantly different from thecontrol basal state (Table 1). Figure 4, C and D, shows the appearanceof an untreated control DRG neuron and a neuron treated with D3-Fc.Simply replacing the medium bathing the cells with fresh controlmedium or with medium containing the MUC-Fc fusion protein didnot induce growth cone collapse. When the cultures were treatedwith saturating concentrations of a collapsin 1-myc/his fusionprotein (Koppel and Raper, 1998), 49% of the growth cone collapsed(data not shown). Thus, the NG2 fusion proteins were as effectiveas collapsins in inducing the collapse of growth cones of newbornrat DRG neurons.

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Figure 4. Domain-specific NG2 proteins induce the collapse of DRG neuron growth cones. DRG sensory neurons were grown on laminin for 7-8 hr and then treated with varying concentrations of NG2 fusion proteins for 30 min, fixed, and analyzed as described in Materials and Methods. A, Dose-response curves showing the collapsing activity of the different NG2 proteins. The percentage of growth cones having a collapsed morphology for each condition (y-axis) is plotted against the concentration of the test protein (x-axis): D1-Fc (), D2-Fc ( $triangle$ ), D1,2-Fc ( $open circle$ ), D3-Fc ( $down-triangle$ ), ECD-myc/his (), and MUC-Fc ( $diamond$ ). B, Effects of treatment of D2-containing fusion proteins with GAG lyases. D2-Fc and D1,2-Fc (10 nM) were treated with the indicated GAG lyases as described in Materials and Methods and then analyzed for growth cone-collapsing activity. C'ase, Digestion with chondroitinase ABC digestion; K'ase, digestion with keratanase. All conditions were significantly different from no-protein controls (p < 0.0001, ANOVA and Scheffé's post hoc test), except C'ase-treated D2-Fc, which was not significantly different from controls. Values shown in A and B are mean ± SEM of two to four separate experiments. In all experiments, at least 100 growth cones were scored in each of duplicate wells per condition tested. C, D, Representative DRG neurons grown under control conditions (C) and fusion protein-treated conditions (D; D3-Fc, 20 nM). The filled arrowheads point to spread growth cones; the open arrowheads point to collapsed growth cones; and the arrows point to unscored growth cones. Scale bar, 20 µm.

We analyzed the role of the CS GAG chains in growth cone collapse by treating the D2-containing fusion proteins with GAG lyasesbefore adding them to the cells. As illustrated in Figure 4B,removal of the GAG chains did not alter the collapse responseinduced by D1,2-Fc. Consistent with the effects of C'ase in theneurite outgrowth assay, removal of the GAG chains from D2-Fcreduced the collapse response to a level not significantly differentfrom that of the control. Treatment of the D2-Fc fusion proteinswith keratanase had no effect on the ability of the fusion proteinto induce growth cone collapse. Thus, as is the case with inhibitionof neurite growth, the CS GAG chains on domain 2 can induce growthcone collapse, but they are not required when core protein regionsfrom domain 1 are present. Consistent with the idea that the GAGchains and protein domains can each independently induce growthcone collapse, we found that the addition of chondroitin 4-sulfatealone at 5 µg/ml increased the total number of collapsed growthcones to 42% (data not shown; p vs control < 0.03; Student's ttest).

Table 1 summarizes the data from both the neurite outgrowth and growth cone collapse assays. When used at 20 nM, there wereno statistically significant differences between the effects ofthe entire ECD and the domain-specific fusion proteins in theseassays. The EC₅₀ values for each fusion protein for either neuriteextension or growth cone collapse, calculated from the data shownin Figures 3 and 4, are similar and in agreement with the K_d forNG2 binding to neurons (Dou and Levine, 1997). The EC₅₀ for D2-Fcin both assays increased twofold to fivefold after removal ofthe GAG chains. This suggests that the central region of the proteincore of NG2 alone has little effect on growing neurons and thatmost of the inhibitory activity can be attributed to the GAG chains.Whether the CS GAG chains directly perturb axon behavior or whetherthey are required to hold domain 2 in a conformation that allowsit to interact with neurons and their growth cones isunknown.

NG2 can exist in multiple configurations

In the assays above, the N-terminal domain 1 and the juxtamembrane domain 3 were equally effective when tested separately,and their individual effects were not statistically differentfrom the effects of the entire ECD. NG2 can exist in several differentforms. In addition to being an integral membrane proteoglycan,it can be secreted or shed from the surfaces of some tissue culturecell lines (Nishiyama et al., 1995). NG2 is found in both solubleand particulate extracts of normal and injured brain, suggestingthat these two forms (a membrane-bound form and a released, extracellularform) occur in vivo (Asher et al., 2001; Jones et al., 2002).These two different structural states suggest the following model.When NG2 is an integral membrane protein, domain 1 may extendaway from the cell surface and be available for interactions withneuronal growth cones. The juxtamembrane domain 3 may be inaccessible.When secreted or shed from the cell surface, NG2 could associatewith the extracellular matrix, perhaps via its central domain2, and then both domains 1 and 3 would be accessible. One wayto test these speculations would be to derive domain-specificantibodies that can neutralize the inhibitory effects of the individualFc fusion proteins and then to determine whether the antibodiescan neutralize the effects of NG2 when presented as either anintegral membrane protein or as an extracellularprotein.

Derivation of domain-specific, neutralizing monoclonal antibodies

To raise domain-specific mAbs, mice were immunized with 293-NG2 cells, which express full-length NG2 as an integral membraneprotein (Chen et al., 2002), and with HEK293 cells, which expressa truncated NG2 containing extracellular domain 3, the transmembranedomain, and the cytoplasmic tail. The domain specificity of theresulting antibodies was assayed with ELISAs, immunoblots, andindirect immunofluorescence of living cells. Here, we describefour antibodies used. Antibody 69, an IgG2a, is directed againstdomain 1 and referred to as anti-D1. Antibody D31.10 (Stallcupet al., 1983), an IgG1, is directed against domain 2 and referredto as anti-D2. Two different antibodies against domain 3 wereused. The first, antibody 132, an IgG1, bound to D3-Fc but didnot neutralize its growth-inhibitory activity. This antibody willbe referred to as anti-D3. A second anti-domain 3 antibody, antibody147, also an IgG1, did neutralize domain 3 (see below) and isreferred to as anti-D3N. The specificity of the different antibodiesin immunoblots is shown in Figure 5.

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Figure 5. Characterization of the domain-specific monoclonal antibodies. Fc-fusion proteins encoding the indicated domains of NG2 were electrophoresed on 6% polyacrylamide gels as described in Materials and Methods and immunoblotted with the different anti-NG2 antibodies. The following antibodies were used: polyclonal rabbit anti-NG2, mAb 69, mAb D31.10, mAb 147, and mAb 132. mAb 69 recognizes D1 but not D2 or D3. mAb D31.10 recognizes D2 with (+) or without ( $-$ ) C'ase treatment, suggesting that the D31.10 epitope resides in the core protein of domain 2. Both mAbs 147 and 132 recognize D3 but not D1 or D2. All of the antibodies used recognize the ECD. Each lane was loaded with 200 ng of protein. The arrows to the left indicate the electrophoretic mobility of molecular weight markers. From top to bottom, they are 185, 121, 86, and 69 kDa.

Monoclonal antibodies block the inhibitory activities of D1,2 and D3

We tested the ability of the different mAbs to neutralize NG2-induced growth inhibition using the neurite outgrowth assayand the Fc fusion proteins described above. (We used D1,2-Fc inthese assays, because the D1-Fc was produced at a low yield andtended to aggregate after storage at $-$ 70°C.) Each protein wasused at 20 nM, and each antibody was used at 5 µg/ml. Figure 6Ashows that anti-D1 completely blocked the inhibitory activityof D1,2-Fc but had no effect on the inhibition of growth on D3-Fc-coatedsurfaces. The anti-D1 mAb also completely reversed the growthinhibition caused by D1-Fc (data not shown). The anti-D2 mAb,which binds to D1,2 to an extent similar to that of anti-D1 (datanot shown), had no effect on the inhibition caused by D1,2-Fc.This suggests that the core protein regions recognized by theanti-D2 mAb make little contribution to the inhibitory effectsof NG2 (Fig. 6B). Treatment of the D3-Fc-coated surfaces withanti-D3N completely reversed the growth inhibition, but treatmentof the surfaces with the same concentration of a second mAb (anti-D3)had no effects. Anti-D3N had no effect on the inhibition causedby D1,2-Fc (Fig. 6C,D). These data demonstrate that the mAbs producedcan neutralize the growth-inhibitory properties of their respectiveantigens with little effect on the activities of other regionsof the large core protein.

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Figure 6. Monoclonal antibodies block neurite growth inhibition caused by the NG2 fusion proteins. Forty-eight-well tissue culture plates were coated with mixtures of L1-Fc and the NG2 fusion proteins and treated with monoclonal antibodies, and neurite lengths were measured for cerebellar granule neurons as described in Materials and Methods. L1-Fc was used at 2.5 µg/ml; D1,2-Fc (D1,2), D3-Fc (D3), and ECD-myc/his (ECD) were used at 20 nM. All the monoclonal antibodies were used at 5 µg/ml. In all panels, neurite growth on substrates coated with L1-Fc alone was measured and used as 0% inhibition and is not shown on the graphs. As shown in A and C, the anti-D1 and anti-D3N antibodies completely block neurite growth inhibition induced by their respective antigens but have no effect on the neurite growth inhibition induced by nonreactive fusion proteins. B, D, The anti-D2 and anti-D3 antibodies do not reverse the growth inhibition induced by their corresponding antigenic fusion proteins. When ECD-myc/his was used as the substrate, anti-D1 or anti-D3N treatment each only partially reversed growth inhibition (E, left). However, when both the anti-D1 and anti-D3N antibodies were used together to treat the ECD substrate, neurite lengths were comparable with those on L1-coated substrates also treated with both antibodies (E, right). Treatment of the ECD-coated substrates with anti-D2 or anti-D2 together with anti-D3 has no effect on the inhibitory activity of the ECD. Data shown are mean ± SEM from at least three independent experiments. In each experiment, neurite lengths were measured from at least 50 neurons for each condition. *Value significantly different from ECD (p < 0.001; Student's t test) but not significantly different from each other (p > 0.1; Student's t test); **value significantly different from ECD (p < 0.001; Student's t test) but not significantly different from each other (p > 0.4; Student's t test).

Both domains 1 and 3 contribute to the inhibition of secreted NG2

To determine which regions of NG2 mediate growth inhibition when the protein is secreted or shed from cells and tissues, wetested the ability of the domain-specific antibodies to neutralizethe inhibitory effects of the ECD-myc/his fusion protein on neuriteoutgrowth. This protein extends from the N terminus to the juxtamembranealanine residue (residue 2223) and encompasses regions containedin all secreted forms of NG2 (Nishiyama et al., 1995). As shownin Figure 6E, anti-D3N and anti-D1, when used alone, only partiallyreversed the inhibitory effects of the ECD. Anti-D2 antibodieshad no effect on this inhibition. We next asked whether pairsof the monoclonal antibodies could reverse more completely theinhibition caused by the ECD. When any two antibodies were used,there was a small reduction in the ability of L1 to promote neuriteextension, probably reflecting some shielding of L1 (Fig. 6E,right panel). However, when the L1- and ECD-coated surfaces weretreated with both anti-D3N and anti-D1, neurite lengths were increasedand became statistically identical to the lengths on the controlL1-coated surfaces. Treatment with pairs of non-neutralizing antibodies,such as anti-D2 and anti-D3, did not reduce the inhibition causedby the ECD. Combining the anti-D2 antibodies with either anti-D1or anti-D3N did not enhance the ability of these neutralizingantibodies to reverse the ECD-mediated growth inhibition (datanot shown). These results support the hypothesis that both domains1 and 3 contribute to the growth-inhibitory activity of NG2 whenit is secreted andextracellular.

Domain 1 accounts for most of the inhibitory activity of membrane-associated NG2

To determine the contributions of domains 1 and 3 to the inhibitory activity of NG2 when it is expressed as an integral membraneprotein, we used our domain-specific antibodies in a membranecarpet assay. Although this assay accurately reflects the growth-modulatingproperties of the tissues or cells from which the membranes areprepared (Tuttle et al., 1995; Chen et al., 2002), it tends tounderestimate the potency of growth-inhibiting membranes. Explantswith little or no neurite outgrowth attach poorly and tend tobe washed away during the vital staining procedures. As shownpreviously (Chen et al., 2002), membranes prepared from NG2-expressing293 cells (293-NG2) inhibited neurite outgrowth from postnatalcerebellar explants in this assay, and treatment of the membraneswith polyclonal anti-NG2 neutralizes this inhibition (Fig. 7).When the 293-NG2 cell membranes were treated with anti-D1 beforemaking the carpets, neurite outgrowth was identical to that onmembranes from untransfected 293 cells, demonstrating completereversal of growth inhibition. Treatment of the 293-NG2 cell membraneswith anti-D3N had no effect on the neurite growth inhibition.As expected from the results above, anti-D2 did not reverse theinhibition. Anti-D1 treatment did not reverse the inhibition frommyelin-associated glycoprotein (MAG)-expressing Chinese hamsterovary cell membranes (data not shown), demonstrating that theneutralizing effect of anti-D1 is specific for NG2. These experimentssuggest that when NG2 is expressed on the cell surface, domain1 accounts for most of its inhibitory activity.

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Figure 7. Domain 1 accounts for most of the inhibition caused by integral membrane NG2. A, Cerebellar explants from postnatal day 5-7 rats were grown for 40-44 hr on membrane carpets prepared from untransfected 293 cells, 293-NG2 cells, and 293-NG2 cell membranes treated with either polyclonal anti-NG2 antibodies or the anti-D1, anti-D2, and anti-D3N monoclonal antibodies. Data shown are mean ± SEM from at least three independent experiments. Between 16 and 34 individual explants were measured for each data point. *p < 0.001 versus HEK-293; Student's t test. B-G, Appearance of the explants on the different membrane substrates: B, 293 cells, C, 293-NG2 cells; D, 293-NG2 cells treated with rabbit anti-NG2; E, 293-NG2 cells treated with anti-D1; F, 293-NG2 cells treated with anti-D2; and G, 293-NG2 cells treated with anti-D3N. Scale bar, 200 µm.

Inhibitory regions of domain 3 are inaccessible when membrane-bound

The data presented above support the model of NG2 action described above. This model hypothesizes that regions of domain 3that are critically important for neurite growth inhibition maybe inaccessible when NG2 is expressed as an integral membraneproteoglycan, but this region becomes accessible when NG2 is secretedor shed from the cell surface. Regions of domain 1, on the otherhand, may be accessible when NG2 is in either the membrane-associatedor secreted conformation. Because the anti-D1 and anti-D3 mAbsdescribed here were selected after screening with an ELISA usingECD-myc/his as a target, they all bind to the extracellular orsecreted forms of NG2. We examined whether the antibodies boundto integral membrane NG2 by indirect immunofluorescence stainingof living 293-NG2 and 293-D3 cells. As shown in Figure 8, anti-D1,anti-D2, and anti-D3 all bound to the surfaces of the 293-NG2cells. Anti-D3N, however, bound much more poorly to the cell surface.Both the anti-D3 and anti-D3N antibodies bound to the surfacesof living 293-D3 cells (Fig. 8M-R). This demonstrates that thefailure of anti-D3N to stain the 293-NG2 cells is not attributableto the antibody but to the accessibility of the antigen. The regionof domain 3 recognized by this neutralizing antibody is only accessiblewhen NG2 is either extracellular or severely truncated in themembrane.

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Figure 8. Anti-D3N antibody has limited binding to NG2 when it is expressed on the cell surface. 293-NG2 (A-L) and 293-D3 (M-R) cells were immunofluorescently stained with anti-NG2 antibodies as described in Materials and Methods. The following antibodies were used: A, D, G, J, M, P, rabbit anti-NG2; B, monoclonal anti-D1; E, monoclonal anti-D2; H, N, monoclonal anti-D3N; and K, Q, monoclonal anti-D3. Each monoclonal antibody was used at 1 µg/ml, and imaging exposure times were identical for each panel. The third vertical column shows the cells using DIC optics. Although anti-D1, anti-D2, and anti-D3 stain the 293-NG2 cells robustly, the signal from anti-D3N staining is significantly weaker. Anti-D3N stains the 293-D3 cells as well as does anti-D3. Scale bar, 50 µm.

  Discussion

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The glial scar that forms after brain or spinal cord injury is a barrier to axon regeneration, and the CSPGs present at theglial scar, together with myelin-associated inhibitory moleculessuch as NOGO, are responsible, at least in part, for these barrierfunctions (Davies et al., 1999; GrandPre et al., 2002). Numerousstudies show that levels of NG2 increase rapidly after injury(Levine, 1994; Ong and Levine, 1999; Zhang et al., 2001; Joneset al., 2002; Moon et al., 2002) and that NG2 can inhibit axongrowth in vitro (Dou and Levine, 1994; Fidler et al., 1999; Chenet al., 2002). Thus, NG2 may be one of the principal CSPGs involvedin preventing axon regeneration. One goal of this study was toidentify the specific regions of the NG2 core protein responsiblefor this inhibition of axongrowth.

The data presented here identify the N-terminal domain 1 and the juxtamembrane domain 3 as two regions of NG2 that can inhibitaxon growth. When presented in a soluble form, NG2 and fragmentsthereof induce growth cone collapse. This novel function for NG2suggests that it is similar to other axon guidance molecules thatcollapse and repel growth cones. The EC₅₀ values for both theinhibition of neurite extension and growth cone collapse are similarto each other and similar to the K_d for NG2 binding to cerebellarneurons (Dou and Levine, 1997), suggesting that these phenomenaare all linked. They suggest a model in which NG2 binds to theneuronal surface and perturbs growth cone functions and structure,and this perturbation subsequently leads to shorteraxons.

The primary structure of NG2 bears little resemblance to other proteins or proteoglycans. This is unusual, because most proteoglycansbelong to extended families of molecules. Despite the uniquenessof its primary structure, NG2 is highly conserved, and NG2-likemolecules have been identified in sea urchins and Caenorhabditiselegans (Hodor et al., 2000; Hutter et al., 2000). In sea urchinembryos, ECM3, an NG2-like molecule, is thought to form a barrierbetween ectoderm and endoderm, a function not unsimilar to theproposed role of CSPGs in the developing nervous system and atglial scars (Snow et al., 1990; Oakley and Tosney, 1991; Fawcettand Asher, 1999; Asher et al., 2001).

Domain 1 alone can induce growth cone collapse and can inhibit neurite extension. This is the first demonstrated functionfor domain 1, which has been difficult to purify and analyze,in part because of its insolubility and tendency to aggregate(Y. M. Ughrin and J. M. Levine, unpublished observations). Domain1 contains two tandem laminin G domains, a globular motif foundin several proteins, including the neurexins, agrin, caspr, andslit (for review, see Timpl et al., 2000). Laminin G domains bindto heparin, sulfatides, and $alpha$ -dystroglycan (Talts et al., 1999)and participate in cell-cell and cell-matrix interactions. Theseinteractions and their cellular effects are complex, in part becauseof the structural diversity of the laminin G domains and theirability to interact cooperatively. For example, the three lamininG domains that are clustered at the C terminus of agrin are notinvolved in the inhibition of neurite outgrowth from ciliary ganglianeurons (Bixby et al., 2002). Similarly, in the case of slit,a soluble axon repellent, axon repulsion is mediated by the N-terminalleucine-rich repeats and not the single laminin G domain (Battyeet al., 2001; Chen et al., 2001). On the other hand, the lamininG domains of Gas6 are sufficient to bind to and activate the Rsereceptor-tyrosine kinase, and the laminin G domains of agrin areresponsible for acetylcholine receptor clustering (Mark et al.,1996; Cornish et al., 1999). Whether the laminin G domains ofdomain 1 are essential for the inhibitory activities demonstratedhere is notknown.

The central domain 2 of NG2 is thought to have an extended but flexible structure, to carry the single covalently attachedCS GAG chain, and to interact with ECM molecules such as collagenV and VI (Tillet et al., 1997; Stallcup and Dahlin-Huppe, 2001).When domain 2 is expressed as a small fusion protein and whenit carries one or more CS GAG chains, it inhibits neurite growthand induces growth cone collapse. This activity is likely attributableto the GAG chains and not the core protein, because when the GAGchains are removed with C'ase, domain 2 is essentially inactive.The lack of an inhibitory function for domain 2 is also supportedby the observation that all the activity of D1,2-Fc can be neutralizedwith an antibody that reacts specifically with domain 1, and thatantibodies against both domain 1 and 3, when used together, completelyneutralize the inhibitory activity of the ECD. In previous studies,we have shown that neither chondroitin sulfate A nor chondroitinsulfate C inhibits L1-stimulated neurite growth from cerebellargranule neurons unless used at concentrations many time higherthan used here (Dou and Levine, 1995). Thus, the role of the GAGchains in axon growth inhibition is uncertain. It is possiblethat the clustered negative charges provided by both the CS GAGchain and regions of domain 2 (Nishiyama et al., 1991) combineto perturb growth cone function, but that when either the domain2 core protein or GAG chains are used individually, the clusterednegative charges on these molecules are insufficient to do so.Alternatively, the GAG chains may hold the flexible domain 2 ina configuration that allows for inhibition ofgrowth.

This finding points out one of the important questions in PG biology: What are the functions of the GAG chains? Several growth-inhibitoryPGs, including NG2, neurocan, and versican, do not require theGAG chains for their neurite growth-inhibitory activities (Douand Levine 1994; Friedlander et al., 1994; Milev et al., 1994;Schmalfeldt et al., 2000). In the case of brevican, however, theCS GAG chains contribute significantly to growth inhibition (Yamadaet al., 1997). The administration of GAG lyases to damaged CNStissue changes the environment in a manner that promotes axonregeneration (Moon et al., 2001; Bradbury et al., 2002; Zuo etal., 2002). This effect is not limited to damaged CNS tissue,because GAG lyases also modify axonal pathfinding behavior indeveloping organisms (Chung et al., 2000; Becker and Becker, 2002).These findings show that the GAG chains are involved in the inhibitionof axon regeneration. Whether this is attributable to a directeffect of the GAGs on regenerating neurons is unknown. Glycosaminoglycanchains organize the structure of the ECM (Yamaguchi, 2000), andthey bind small molecules, including growth factors (Milev etal., 1998a,b; Goretzki et al., 1999). In the case of phosphacanand NG2, the CS GAG chains increase the affinity of the proteinfor neuritogenic factors such as bFGF. Thus, it is possible thatCSPGs might sequester growth factors, and on degradation of theGAG chains, these molecules may be released and then be able tointeract with their neuronal receptors. Furthermore, the associationof cell surface PGs such as NG2 with membrane-type matrix metalloproteinases(MMPs) is dependent on the CS GAG chains (Iida et al., 2001).Removal of the GAG chains in vivo might also release proteasesthat could have complex effects on the structure of the glialscar and its ability to act as a barrier for axonregeneration.

Little is known about the structure of the juxtamembrane domain 3, although it participates in multiple functions, includinggrowth factor binding, plasminogen binding, and, as shown here,perturbation of growth cone function (Goretzki et al., 1999, 2000).The inhibitory activity of a fusion protein containing only domain3 is quantitatively similar to the activities of either domain1 alone or the entire ECD of NG2. This supports the idea thatthe separate domains of the NG2 core protein are independent andredundant functional units (Goretzki et al., 1999, 2000).

This redundancy has important implications for how NG2 might act to inhibit axon regeneration at sites of CNS injury. AlthoughNG2 is found predominantly as an integral membrane protein, itcan be secreted or shed from the cell surface via extracellularproteolysis (Nishiyama et al., 1995). The secretion of NG2 isthought to occur at glial scars (Asher et al., 2001; Jones etal., 2002). Little is known about how this proteolytic event maybe regulated. Although NG2 is a good substrate for MMP3, mRNAsencoding MMP3 have not been detected in the damaged CNS (Muiret al., 2002). Despite these uncertainties, it is clear that levelsof NG2 increase after brain or spinal cord injury (Levine, 1994;Asher et al., 2001; Zhang et al., 2001; Jones et al., 2002). Thusit is possible that damage increases the accessibility of NG2as it does for other growth-inhibitory molecules such as MAG,which is normally associated with the axon-myelin interface butcan be released in a soluble form after injury (Trapp et al.,1989; Tang et al., 1997, 2001). The monoclonal antibody stainingdata shown in Figure 8 suggest that when NG2 is an integral membraneprotein, regions within domain 3 that are likely to be directlyinvolved in growth inhibition are probably inaccessible. In thissituation, domain 1 is sufficient to inhibit growth. When NG2is secreted or shed from the cell surface, parts of domain 3 wouldbecome accessible. Thus multiple regions of NG2 can inhibit axonregeneration in vivo depending on the conformational state ofthe molecule. Blocking inhibitory molecules with antibodies hasbeen one of several strategies that can promote regeneration inexperimentally injured animals (Fouad et al., 2001). These tworegions, domains 1 and 3, will be important targets for immunologicalneutralization in future studies of axon regeneration in vivo.

  FOOTNOTES

Received Aug. 20, 2002; revised Oct. 8, 2002; accepted Oct. 11, 2002.

^* Y.M.U. and Z.J.C. contributed equally to thiswork.

This work was supported by grants from the National Institutes of Health and the Christopher Reeve Paralysis Foundation. Wethank Dr. V. Lemmon and J. Raper for gifts ofplasmids.

Correspondence should be addressed to Dr. Joel M. Levine at the above address. E-mail: joel.levine{at}sunysb.edu.

  References

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
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