Schwann cell type V collagen inhibits axonal outgrowth and promotes Schwann cell migration via distinct adhesive activities of the collagen and noncollagen domains.

Previously, we reported the cloning of alpha4 type V collagen, a novel member of the collagen type V gene family that is expressed by Schwann cells in developing peripheral nerves (Chernousov et al., 2000). The present study was performed to investigate the effects of this collagen on the adhesion and migration of premyelinating Schwann cells and neurite outgrowth from embryonic dorsal root ganglion neurons. Purified alpha4(V)-containing collagen isolated from Schwann cell conditioned medium (collagen type V(SC)) promoted migration of Schwann cells but inhibited outgrowth of axons from rat embryo dorsal root ganglia. Collagen type V(SC) blocked axonal outgrowth in the presence of otherwise active substrates such as collagen type IV, indicative of active inhibition. The noncollagen N-terminal domain of alpha4(V) promoted Schwann cell adhesion, spreading, and migration. These processes were inhibited by soluble heparin but not by function-blocking antibodies against alpha1- and alpha2-integrins. The collagen domain of pepsin-digested collagen type V was poorly adhesive for Schwann cells. The type V collagen domain but not the alpha4(V) N-terminal domain blocked neurite outgrowth from dorsal root ganglion neurons. In cocultures of dorsal root ganglion neurons and Schwann cells, collagen type V(SC) promoted axon fasciculation and association of axons with Schwann cells. These results suggest that in embryonic peripheral nerves, collagen type V(SC) plays a dual role in regulating cell migration. This represents a heretofore unrecognized function of peripheral nerve collagen fibrils in regulating patterns of peripheral nerve growth during development.

Schwann cells synthesize type V collagen that contains a novel alpha 4 chain. Molecular cloning, biochemical characterization, and high affinity heparin binding of alpha 4(V) collagen.

Previously, we reported the isolation of a heparan sulfate-binding collagenous protein, p200, that is expressed by Schwann cells in developing peripheral nerves ((1996) J. Biol. Chem. 271, 13844-13853; (1999) J. Neurosci. Res. 56, 284-294). Here, we report the cloning of p200 cDNA from a Schwann cell cDNA library. The deduced amino acid sequence identifies p200 as a novel member of the collagen type V gene family. This polypeptide, which we have named alpha4 type V (alpha4(V)) collagen, contains an uninterrupted Gly-X-X collagen domain of 1011 amino acids that shows 82% sequence identity to human alpha3(V) collagen and 71% identity to rat alpha1(V) collagen. alpha4(V) is secreted by Schwann cells as a collagen heterotrimer that also contains alpha1(V) chains. alpha4(V)-containing collagen molecules synthesized by Schwann cells retain their amino-terminal non-collagenous domains. alpha4(V) mRNA was detected by reverse transcriptase-linked polymerase chain reaction amplification in neonatal and adult brain and neonatal peripheral nerve. alpha4(V) mRNA and protein were not detected in most other tissues, including the placenta and heart, which are known to contain alpha3(V). This pattern of alpha4(V) expression contrasted with that of alpha1(V) mRNA and protein, which were ubiquitously expressed. The isolated alpha4(V) chain demonstrated an unusually high affinity for heparin. The restricted expression and unusual properties of alpha4(V)-containing collagen type V molecules suggest a unique and important role for these molecules in peripheral nerve development.

p200, a collagen secreted by Schwann cells, is expressed in developing nerves and in adult nerves following axotomy.

Previously we reported that cultured rat Schwann cells secrete p200, a collagen-like heparin-binding adhesive glycoprotein with a restricted pattern of expression. Here we report that p200 is secreted as a stable trimer, but only after treatment of Schwann cells with ascorbic acid, and was deposited in the fibrillar extracellular matrix. Heparin and heparitinase treatment inhibited incorporation of p200 into extracellular matrix, suggesting the involvement of Schwann cell heparan sulfate proteoglycans in this process. Pepsin digestion revealed that p200 secreted by ascorbate-treated cells contains a collagenous domain of approximately 140 kDa. Immunofluorescent staining of rat embryos at different ages showed that p200 first appeared between embryonic days 15 and 18, and was confined to peripheral nerves. Staining of adult peripheral nerve was negative, but p200 expression was induced in adult sciatic nerve following nerve transection. These data suggest that p200 carries out unique functions during peripheral nerve development and regeneration and that its expression by Schwann cells is regulated by axon-Schwann cell interaction.

Synergistic regulation of Schwann cell proliferation by heregulin and forskolin.

A peptide corresponding to the epidermal growth factor homology domain of beta-heregulin stimulated autophosphorylation of the heregulin receptors erbB2 and erbB3 in Schwann cells and activation of the mitogen-activated protein (MAP) kinases ERK1 and ERK2. Heregulin-dependent activation of PAK65, a component of the stress-activated signaling pathway, ribosomal S6 kinase, and a cyclic AMP (cAMP) response element binding protein (CREB) kinase, identified as p95(RSK2), was also observed. Receptor phosphorylation and activation of these kinases in response to heregulin occurred in the absence of forskolin stimulation and were not augmented in cells treated with forskolin, a direct activator of adenylyl cyclase. Schwann cell proliferation in response to heregulin was observed only when the cells were also exposed to an agent that elevates cAMP levels. In the absence of heregulin, elevation of cAMP levels failed to stimulate Schwann cell proliferation. Forskolin significantly enhanced heregulin-stimulated expression of cyclin D and phosphorylation of the retinoblastoma gene product. In cells treated with both heregulin and forskolin there was a sustained accumulation of phospho-CREB, which was not observed in cells treated with either agent alone. Heregulin and forskolin synergistically activated transcription of a cyclin D promoter construct. These results demonstrate that heregulin-stimulated activation of MAP kinase is not sufficient to induce maximal Schwann cell proliferation. Expression of critical cell cycle regulatory proteins and cell division require activation of both heregulin and cAMP-dependent processes.

Schwann cells use a novel collagen-dependent mechanism for fibronectin fibril assembly.

Cultured rat Schwann cells were stimulated to deposit fibrillar extracellular matrix by treatment with ascorbic acid in the absence of nerve cells. Immunofluoresence staining of the matrix showed that it contains collagens types I and IV, fibronectin and perlecan but not laminin. Collagen type IV, fibronectin and perlecan co-distributed completely in the matrix fibrils, whereas collagen type I was present in only a subset of these fibrils. Time course studies indicated that collagen type I fibrils appear at late stages of matrix formation. Digestion of Schwann cell extracellular matrix with collagenase effectively disrupted most of the matrix including fibronectin fibrils. This was in contrast with fibroblasts, where collagenase treatment removed collagen with no visible effect on fibronectin fibrils. alpha5 integrin was expressed on the cell surface of Schwann cells and partially codistributed with fibronectin-containing fibrils. This suggests that the inability of Schwann cells to deposit fibronectin-containing matrix through a conventional, collagen-independent mechanism was not due to the lack of fibronectin-binding integrins on their cell surface. Polyclonal anti-fibronectin antibodies inhibited the deposition of fibronectin into the matrix fibrils, whereas collagen type IV fibrils were generally unaffected. Growth of Schwann cells on collagen type IV-coated substrate in the absence of ascorbate induced deposition of fine fibronectin fibrils. These results suggest that Schwann cells use an apparently novel, collagen type IV-dependent mechanism for the deposition of fibronectin into their extracellular matrix.

Syndecan-1 expression is down-regulated during myoblast terminal differentiation. Modulation by growth factors and retinoic acid.

Syndecan-1 is an integral membrane proteoglycan involved in the interaction of cells with extracellular matrix proteins and growth factors. It is transiently expressed in several condensing mesenchymal tissues after epithelial induction. In this study we evaluated the expression of syndecan-1 during skeletal muscle differentiation. The expression of syndecan-1 as determined by Northern blot analyses and immunofluorescence microscopy is down-regulated during differentiation. The transcriptional activity of a syndecan-1 promoter construct is also down-regulated in differentiating muscle cells. The decrease in syndecan-1 gene expression is not dependent on the presence of E-boxes, binding sites for the MyoD family of transcription factors in the promoter region, or myogenin expression. Deletion of the region containing the E-boxes or treatment of differentiating cells with sodium butyrate, an inhibitor of myogenin expression, had no effect on syndecan-1 expression. Basic fibroblast growth factor and transforming growth factor type beta, which are inhibitors of myogenesis, had little effect on syndecan-1 expression. When added together, however, they induced syndecan-1 expression. Retinoic acid, an inducer of myogenesis, inhibited syndecan-1 expression and abolished the effect of the growth factors. These results indicate that syndecan-1 expression is down-regulated during myogenesis and that growth factors and retinoic acid modulate syndecan-1 expression by a mechanism that is independent of myogenin.

Developmental and cell-type-specific expression of cell surface heparan sulfate proteoglycans in the rat heart.

The expression of cell surface heparan sulfate proteoglycans in rat heart was investigated by Northern blot analysis with specific cDNA probes. In adult heart syndecan-3 and glypican mRNAs were abundantly expressed. Lower levels of syndecan-2 mRNA and very low levels of syndecan-1 mRNA were also detected. Analysis of RNA isolated from hearts of rats of various ages revealed that syndecan-3 and glypican mRNAs levels increased dramatically at birth, and continued to be expressed at high levels in adult animals. To determine which of these proteoglycans was expressed in cardiomyocytes, primary cultures of cardiomyocytes and nonmyocytes isolated from neonatal rat hearts were analyzed for proteoglycan expression. Glypican mRNA was localized almost exclusively to cardiomyocytes. Syndecan-3 mRNA was not detected in myocytes, but was detected in the nonmyocyte cells. Biochemical characterization of cardiomyocyte glypican revealed that it was a phosphatidylinositol-anchored heparan sulfate proteoglycan. Results of immunofluorescent staining of rat hearts with anti-glypican antibodies were consistent with the Northern blot data, and localized glypican to the lateral regions of myocyte plasma membrane that contact the basement membrane, as well as sites of myocyte adhesion junctions. At the latter site glypican colocalized with vinculin. Visualization of basic fibroblast growth factor binding sites by means of a tissue slice overlay assay also revealed colocalization with glypican. These results demonstrate developmental and cell-type-specific expression of membrane heparan sulfate proteoglycans in the heart. They also show that glypican is a major heparan sulfate proteoglycan expressed on the cardiomyocyte plasma membrane.

cDNA cloning, genomic organization, and in vivo expression of rat N-syndecan.

The amino acid sequence of rat N-syndecan core protein was deduced from the cloned cDNA sequence. The sequence predicts a core protein of 442 amino acids with six structural domains: an NH2-terminal signal peptide, a membrane distal glycosaminoglycan attachment domain, a mucin homology domain, a membrane proximal glycosaminoglycan attachment domain, a single transmembrane domain, and a noncatalytic COOH-terminal cytoplasmic domain. Transfection of human 293 cells resulted in the expression of N-syndecan that was modified by heparan sulfate chain addition. Heparitinase digestion of the expressed proteoglycan produced a core protein that migrated on SDS-polyacrylamide gels at an apparent molecular weight of 120, 000, identical to N-syndecan synthesized by neonatal rat brain or Schwann cells. Rat genomic DNA coding for N-syndecan was isolated by hybridization screening. The rat N-syndecan gene is comprised of five exons. Each exon corresponds to a specific core protein structural domain, with the exception of the fifth exon, which contains the coding information for both the transmembrane and cytoplasmic domains as well as the 3'-untranslated region of the mRNA. The first intron is large, with a length of 22 kilobases. The expression of N-syndecan was investigated in late embryonic, neonatal, and adult rats by immunoblotting and Northern blotting analysis. Among the tissues and developmental stages studied, high levels of N-syndecan expression were restricted to the early postnatal nervous system. N-syndecan was expressed in all regions of the nervous system, including cortex, midbrain, spinal cord, and peripheral nerve. Immunohistochemical staining revealed high levels of N-syndecan expression in all brain regions and fiber tract areas.

Schwann cells secrete a novel collagen-like adhesive protein that binds N-syndecan.

A heparin-binding glycoprotein was purified from conditioned medium of cultured rat Schwann cells. The protein, p200, which has an apparent molecular mass of approximately 200 kDa, was identified by its ability to bind the cell surface heparan sulfate proteoglycan N-syndecan (syndecan-3) in a membrane overlay assay. Soluble heparin but not chondroitin sulfate inhibited the binding, suggesting the involvement of heparan sulfate chains of proteoglycan in the interaction. Purified p200 promoted the attachment and spreading of Schwann cells. Adhesion to p200 was blocked by heparin, suggesting that heparan sulfate proteoglycans are cell surface receptors for p200. The tissue distribution of p200 was determined by immunoblot analysis with anti-p200 antibodies. Among neonatal rat tissues examined p200 was detected only in sciatic nerve and, at lower levels, in skeletal muscle. p200 expression in sciatic nerve was detectable only during the first 2-3 weeks of postnatal development and was not detected in adult rats. Immunofluorescent staining of rat sciatic nerve showed that p200 was localized in the extracellular matrix surrounding individual Schwann cells-axon units. Two tryptic peptides from p200 were purified and sequenced. These contained multiple GXX collagen-like repeats. Bacterial collagenase digestion of p200 produced a product with an apparent molecular mass of approximately 90 kDa. These data suggest that Schwann cells secrete an apparently novel collagen-like adhesive protein that interacts with cells through cell surface heparan sulfate proteoglycans.

The cytoplasmic domain of syndecan-1 is required for cytoskeleton association but not detergent insolubility. Identification of essential cytoplasmic domain residues.

Syndecan-1 is a member of a gene family of multifunctional transmembrane heparan sulfate proteoglycans that bind a variety of extracellular ligands and possess highly conserved non-catalytic cytoplasmic domains. It has been shown that antibody-mediated clustering of syndecan-1 causes the proteoglycan to become associated with microfilaments and insoluble in non-ionic detergent. A series of truncation and point mutations of the syndecan-1 core protein was constructed to identify specific structural features that were required for these characteristics. The transmembrane domain but not the cytoplasmic domain was required for cell surface expression of syndecan-1. Deletion of the COOH-terminal 11 amino acids of the cytoplasmic domain had no effect, while deletion of an additional 12 amino acids abolished microfilament association. Mutation of a conserved tyrosine residue within the latter region also abolished microfilament association. In contrast, mutation of 2 tyrosine residues outside this region had no effect. Deletion of the entire cytoplasmic domain (except for a short stop-transfer sequence) did not affect insolubility of the proteoglycan in detergent. Analysis of a form of syndecan-1 that lacked glycosaminoglycan acceptor sites revealed that covalently attached glycosaminoglycans were not required for cell surface expression, microfilament association, or detergent insolubility. These results demonstrate that microfilament association is a function of a subregion within the cytoplasmic domain and suggest that insolubility in detergent is a function of the transmembrane domain.

Aggregation-induced association of syndecan-1 with microfilaments mediated by the cytoplasmic domain.

Expression of the transmembrane proteoglycan syndecan-1 in Schwann cells leads to enhanced spreading and cytoskeletal reorganization, but without an apparent stable association of syndecan-1 with cytoskeletal structures such as focal adhesions. Since cell surface oligomerization may be a mechanism for regulating the activities of transmembrane receptors, we wanted to investigate whether antibody-induced aggregation of the proteoglycan would promote its association with the cytoskeleton. When syndecan-1-expressing cells were incubated with anti-syndecan-1 and anti-IgG antibodies, clustering of proteoglycan on the cell surface was observed by immunofluorescence microscopy. The resulting pattern of syndecan-1 distribution was very similar to that of the underlying microfilament network, as visualized by fluorescent-phalloidin staining. In cells that were fixed briefly with paraformaldehyde before addition of the anti-IgG antibodies no such colocalization of syndecan-1 and microfilaments was observed. Additional findings supported the conclusion that this pattern of syndecan-1 distribution reflected an association with microfilaments: aggregated syndecan-1 was resistant to extraction by nonionic detergent; incubation of the cells with cytochalasin b, but not colchicine, altered the pattern of aggregated syndecan-1 distribution; antibody-induced clustering of syndecan-1 led to a reorganization of actin filaments. Syndecan-1 remained on the cell surface following antibody-induced clustering, as revealed by immunogold staining and transmission electron microscopy. A mutant form of syndecan-1 lacking most of the cytoplasmic domain failed to exhibit actin filament association or induce actin reorganization following antibody-mediated aggregation. These results suggest that transient associations of syndecan family proteoglycans with microfilaments may be important aspects of their biological functions.

Molecular cloning and characterization of an isoprenylated 67 kDa protein.

The cDNA coding for a 67 kDa protein (p67) was isolated from a rat Schwann cell library. A recombinant form of p67 expressed in bacteria was used to produce polyclonal anti-p67 antibodies. By immunoblot analysis p67 was found to be expressed in most tissues and cell lines examined. Inspection of the deduced amino acid sequence revealed a COOH-terminal consensus sequence for isoprenylation. Consistent with this finding, p67 was a substrate for isoprenylation in vitro by geranylgeranylpyrophosphate. p67 was associated predominantly with the particulate fraction of rat smooth muscle cells. The rat p67 sequence was highly homologous to a family of recently described human and mouse gamma-interferon inducible, guanine nucleotide binding proteins.

Syndecan-1 expressed in Schwann cells causes morphological transformation and cytoskeletal reorganization and associates with actin during cell spreading.

To investigate the biological functions of transmembrane proteoglycans we have produced clonal cell lines of rat Schwann cells that express the hybrid proteoglycan syndecan-1. This was done by transfection of newborn rat Schwann cells with a plasmid vector bearing the rat syndecan-1 cDNA sequence under transcriptional control of the constitutively active cytomegalovirus promoter, and a neomycin resistance gene. Stably expressing cells were selected by growth in G418. Expression of syndecan-1 was verified by Northern and immunoblot analysis and immunoprecipitation of 35SO4-labeled proteoglycans. The syndecan-1 expressing cells exhibited significantly enhanced spreading on several different substrata, including fibronectin and laminin, and an altered morphology. The enhanced spreading appeared to result from the presence of syndecan-1, based on the observation that anti-syndecan-1 antibodies inhibited the enhanced substratum spreading. There was also a reorganization of cytoskeletal structures and formation of focal adhesions, visualized by anti-vinculin staining, which were absent from control Schwann cells. There was no apparent stable association of cell surface syndecan-1 with focal contact sites, as determined by dual staining with anti-syndecan-1 and anti-vinculin antibodies. Colocalization of patches of cell surface syndecan-1 with actin was observed, but only during cell spreading. These findings provide evidence for a role of transmembrane proteoglycans in cellular morphogenesis, and suggest that transient association of syndecans with microfilaments may be an important aspect of their biological function.

Processing and subcellular distribution of the Schwann cell lipid-anchored heparan sulfate proteoglycan and identification as glypican.

We previously identified a phosphatidylinositol-specific phospholipase c (PI-PLC)-releasable heparan sulfate proteoglycan (HSPG) on the surface of rat Schwann cells (D. J. Carey and R. C. Stahl, J. Cell Biol. 111, 2053-2062, 1990). The present study was carried out to investigate the localization and processing of this proteoglycan. The HSPG was synthesized as a PI-PLC-releasable form that was shed into the culture medium with a T1/2 of 17 h. Degradation of the HSPG was negligible. The HSPG was present on the surface of Schwann cells on small (100-200 nm diameter) cylindrical membrane extensions that resembled filopodia. In neonatal peripheral nerve, brain, heart, and striated muscle the HSPG was found to be localized principally to regions of the cell surface that were in contact with basement membranes. Northern blot analysis with cDNA coding for rat glypican (a previously described human fibroblast HSPG) demonstrated abundant expression of glypican mRNA in Schwann cells. Antibodies made against recombinant rat glypican core protein immunoprecipitated the Schwann cell PI-PLC-releasable HSPG. These data demonstrate that the Schwann cell HSPG is rat glypican and support the hypothesis that this proteoglycan functions in cell-extracellular matrix interactions.

Differential expression of transmembrane proteoglycans in vascular smooth muscle cells.

Rat aortic vascular smooth muscle (VSM) cells synthesize the transmembrane proteoglycan syndecan (Cizmeci-Smith, G., Asundi, V., Stahl, R. C., Teichman, L. J., Chernousov, M., Cowan, K., and Carey, D. J. (1992) J. Biol. Chem. 267, 15729-15736). The present work demonstrated that VSM cells synthesize the related transmembrane proteoglycan fibroglycan and that increased expression of these two proteoglycans is stimulated under different conditions. Fibroglycan synthesis by cultured rat aortic VSM cells was demonstrated by Northern blot analysis with a rat fibroglycan cDNA probe and immunoblot analysis with anti-rat fibroglycan antibodies. Effects of growth factors and vasoactive substances on syndecan and fibroglycan expression were examined by Northern blot analysis. Syndecan mRNA levels increased in response to stimulation of VSM cells with serum, platelet-derived growth factor, or angiotensin II. VSM cells stimulated with platelet-derived growth factor contained more syndecan core protein and processed syndecan than control cells. Fibroglycan mRNA levels either decreased or remained unchanged in response to these agents. Fibroglycan mRNA levels increased following transforming growth factor-beta stimulation, while syndecan mRNA levels decreased. Other agents, including basic fibroblast growth factor, endothelin, and carbacyclin did not alter the expression of either proteoglycan. Syndecan and fibroglycan mRNA levels also varied as a function of cell density. These data demonstrate that syndecan and fibroglycan expression are regulated differently in VSM cells and lend support to the hypothesis that these proteoglycans carry out distinct physiological functions.

Regulated expression of syndecan in vascular smooth muscle cells and cloning of rat syndecan core protein cDNA.

cDNA encoding the core protein of rat syndecan was cloned from a neonatal rat aortic cDNA library by polymerase chain reaction amplification. Expression of syndecan mRNA in rat aortic vascular smooth muscle (VSM) cells was demonstrated by reverse transcriptase-linked polymerase chain reaction amplification of syndecan sequences using total RNA from rat aortic VSM cells as templates. Polyclonal antibodies against rat syndecan core protein were produced by immunizing rabbits with a recombinant fusion protein containing a fragment of the extracellular domain. The anti-syndecan antibodies immunoprecipitated a large 35SO4-labeled molecule synthesized by cultured rat aortic VSM cells. The immunoprecipitated molecule was identified as a hybrid proteoglycan, based on results of alkaline, nitrous acid, and chondroitinase ABC digestions. On immunoblots the antibodies recognized a proteoglycan of greater than 200 kDa, with a core protein size after deglycosylation of approximately 50 kDa. The anti-syndecan antibodies stained cultured rat aortic VSM cells as well as tissue sections of neonatal and adult rat aortas in the medial, smooth muscle layer. On Northern blots of RNA isolated from cultured VSM cells, a syndecan cDNA probe hybridized to a major RNA species of 2.6 kilobases. Quantitative Northern blot analysis of total RNA isolated from VSM cells harvested at different cell densities revealed a decrease in syndecan mRNA levels with increased cell density. These results demonstrate the regulated synthesis of syndecan by rat VSM cells.

Molecular cloning and characterization of N-syndecan, a novel transmembrane heparan sulfate proteoglycan.

A cDNA clone coding for a membrane proteoglycan core protein was isolated from a neonatal rat Schwann cell cDNA library by screening with an oligonucleotide based on a conserved sequence in cDNAs coding for previously described proteoglycan core proteins. Primer extension and polymerase chain reaction amplification were used to obtain additional 5' protein coding sequences. The deduced amino acid sequence predicted a 353 amino acid polypeptide with a single membrane spanning segment and a 34 amino acid hydrophilic COOH-terminal cytoplasmic domain. The putative extracellular domain contains three potential glycosaminoglycan attachment sites, as well as a domain rich in Thr and Pro residues. Analysis of the cDNA and deduced amino acid sequences revealed a high degree of identity with the transmembrane and cytoplasmic domains of previously described proteoglycans but a unique extracellular domain sequence. On Northern blots the cDNA hybridized to a single 5.6-kb mRNA that was present in Schwann cells, neonatal rat brain, rat heart, and rat smooth muscle cells. A 16-kD protein fragment encoded by the cDNA was expressed in bacteria and used to immunize rabbits. The resulting antibodies reacted on immunoblots with the core protein of a detergent extracted heparan sulfate proteoglycan. The core protein had an apparent mass of 120 kD. When the anti-core protein antibodies were used to stain tissue sections immunoreactivity was present in peripheral nerve, newborn rat brain, heart, aorta, and other neonatal tissues. A ribonuclease protection assay was used to quantitate levels of the core protein mRNA. High levels were found in neonatal rat brain, heart, and Schwann cells. The mRNA was barely detectable in neonatal or adult liver, or adult brain.

Association of cell surface heparan sulfate proteoglycans of Schwann cells with extracellular matrix proteins.

The terminal differentiation of Schwann cells is dependent on contact with basement membrane. The present study was undertaken to investigate the role of cell surface heparan sulfate proteoglycans (HSPGs) in mediating Schwann cell responses to extracellular matrix contact. Phosphatidylinositol-specific phospholipase C-releasable cell surface HSPGs purified from cultures of neonatal rat Schwann cells were subjected to affinity chromatography on immobilized laminin and fibronectin. Binding of the HSPG to both affinity matrices was observed. The strength of the association, however, was sensitive to the ionic strength of the buffer. In 0.1 M Tris-HCl, HSPG binding was essentially irreversible whereas in physiological ionic strength buffer (e.g. 0.142 M NaCl, 10 mM Tris), weaker binding was detected as a delay in elution of the HSPG from the affinity columns. Further studies of HSPG-laminin binding suggested that the binding was mediated by the glycosaminoglycan chains of the proteoglycans. Results of equilibrium gel filtration chromatography provided additional evidence for a reversible association of the HSPG and laminin with a Kd of approximately 1 x 10(-6) M. When Schwann cells were plated on plastic dishes coated with laminin, the cells attached and extended long slender processes. Inclusion of heparin, but not chondroitin sulfate, in the assay medium resulted in partial inhibition of process extension, but at concentrations of heparin which were higher than that needed to disrupt laminin-HSPG association in vitro. Addition of anti-integrin receptor antibodies resulted in more extensive inhibition of laminin-dependent process extension. Anti-integrin antibodies plus heparin essentially totally inhibited laminin-dependent process extension. These results demonstrate that cell surface HSPGs are capable of reversible association with extracellular matrix molecules and suggest that HSPG-laminin interactions play a role in laminin-dependent Schwann cell spreading.

Identification of a lipid-anchored heparan sulfate proteoglycan in Schwann cells.

Schwann cells synthesize both hydrophobic and peripheral cell surface heparan sulfate proteoglycans (HSPGs). Previous analysis of the kinetics of radiolabeling suggested the peripheral HSPGs are derived from the membrane-anchored forms (Carey, D., and D. Evans. 1989. J. Cell Biol. 108:1891-1897). Peripheral cell surface HSPGs were purified from phytic acid extracts of cultured neonatal rat sciatic nerve Schwann cells by anion exchange, gel filtration, and laminin-affinity chromatography. Approximately 250 micrograms of HSPG protein was obtained from 2 X 10(9) cells with an estimated recovery of 23% and an overall purification of approximately 2000-fold. SDS-PAGE analysis indicated the absence of non-HSPG proteins in the purified material. Analysis of heparinase digestion products revealed the presence of at least six core protein species ranging in molecular weight from 57,000 to 185,000. The purified HSPGs were used to produce polyclonal antisera in rabbits. The antisera immunoprecipitated a subpopulation of 35SO4-labeled HSPGs that were released from Schwann cells by incubation in medium containing phosphatidylinositol-specific phospholipase C (PI-PLC); smaller amounts of immunoprecipated HSPGs were also present in phytic acid extracts. In the presence of excess unlabeled PI-PLC-released proteins, immunoprecipitation of phytic acid-solubilized HSPGs was inhibited. SDS-PAGE analysis of proteins immunoprecipitated from extracts of [35S]methionine labeled Schwann cells demonstrated that the antisera precipitated an HSPG species that was present in the pool of proteins released by PI-PLC, with smaller amounts present in phytic acid extracts. Nitrous acid degradation of the immunoprecipitated proteins produced a single 67,000-Mr core protein. When used for indirect immunofluorescence labeling, the antisera stained the external surface of cultured Schwann cells. Preincubation of the cultures in medium containing PI-PLC but not phytic acid significantly reduced the cell surface staining. The antisera stained the outer ring of Schwann cell membrane in sections of adult rat sciatic nerve but did not stain myelin or axonal membranes. This localization suggests the HSPG may play a role in binding the Schwann cell plasma membrane to the adjacent basement membrane surrounding the individual axon-Schwann cell units.