Heparin-binding proteins HB-GAM (pleiotrophin) and amphoterin in the regulation of cell motility.

Fractionation of proteins from perinatal rat brain was monitored using a neurite outgrowth assay. Two neurite-promoting proteins, HB-GAM (heparin-binding growth-associated molecule; also known as pleiotrophin) and amphoterin, were isolated, cloned and produced by baculovirus expression for structural and functional studies. HB-GAM is highly expressed in embryonic and early post-natal fiber pathways of the nervous system, and it enhances axonal growth/guidance by binding to N-syndecan (syndecan-3) at the neuron surface. N-syndecan in turn communicates with the cytoskeleton through the cortactin/src-kinase pathway to enhance neurite extension. In addition to N-syndecan, the chondroitin sulfate proteoglycan RPTP beta/zeta (receptor-type tyrosine phosphatase beta/zeta) is implicated in the receptor mechanism of HB-GAM. HB-GAM is also prominently expressed in developing and regenerating bone as a matrix-bound cue for migration of osteoblasts/osteoblast precursors to the site of bone deposition. HB-GAM is suggested to regulate motility in osteoblasts through a similar mechanism as in neurons. Structural studies using heteronuclear NMR reveal two similar protein domains in HB-GAM, both consisting of three anti-parallel beta-strands. Search of sequence databases shows that the beta structures of HB-GAM and of the similar domains of MK (midkine) correspond to the thrombospondin type I (TSR) sequence motif. We suggest that the TSR sequence motif, found in several neurite outgrowth-promoting and other cell surface and matrix-binding proteins, defines a beta structure similar to those found in HB-GAM and MK. In general, amphoterin is highly expressed in immature and transformed cells. We suggest a model, according to which amphoterin is an autocrine/paracrine regulator of invasive migration. Amphoterin binds to RAGE (receptor of advanced glycation end products), an immunoglubulin superfamily member related to N-CAM (neural cell adhesion molecule), that communicates with the GTPases Cdc42 and Rac to regulate cell motility. In addition, ligation of RAGE by amphoterin activates NF-kappaB to regulate transcription.

Heparin-binding growth-associated molecule contains two heparin-binding beta -sheet domains that are homologous to the thrombospondin type I repeat.

Heparin-binding growth-associated molecule (HB-GAM) is an extracellular matrix-associated protein implicated in the development and plasticity of neuronal connections of brain. Binding to cell surface heparan sulfate is indispensable for the biological activity of HB-GAM. In the present paper we have studied the structure of recombinant HB-GAM using heteronuclear NMR. These studies show that HB-GAM contains two beta-sheet domains connected by a flexible linker. Both of these domains contain three antiparallel beta-strands. In addition to this domain structure, HB-GAM contains the N- and C-terminal lysine-rich sequences that lack a detectable structure and appear to form random coils. Studies using CD and NMR spectroscopy suggest that HB-GAM undergoes a conformational change upon binding to heparin, and that the binding occurs primarily to the beta-sheet domains of the protein. Search of sequence data bases shows that the beta-sheet domains of HB-GAM are homologous to the thrombospondin type I repeat (TSR). Sequence comparisions show that the beta-sheet structures found previously in midkine, a protein homologous with HB-GAM, also correspond to the TSR motif. We suggest that the TSR sequence motif found in various extracellular proteins defines a beta-sheet structure similar to that found in HB-GAM and midkine. In addition to the apparent structural similarity, a similarity in biological functions is suggested by the occurrence of the TSR sequence motif in a wide variety of proteins that mediate cell-to-extracellular matrix and cell-to-cell interactions, in which the TSR domain mediates specific cell surface binding.

Osteoblast recruitment and bone formation enhanced by cell matrix-associated heparin-binding growth-associated molecule (HB-GAM).

Bone has an enormous capacity for growth, regeneration, and remodeling. This capacity is largely due to induction of osteoblasts that are recruited to the site of bone formation. The recruitment of osteoblasts has not been fully elucidated, though the immediate environment of the cells is likely to play a role via cell- matrix interactions. We show here that heparin-binding growth-associated molecule (HB-GAM), an extracellular matrix-associated protein that enhances migratory responses in neurons, is prominently expressed in the cell matrices that act as target substrates for bone formation. Intriguingly, N-syndecan, which acts as a receptor for HB-GAM, is expressed by osteoblasts/osteoblast precursors, whose ultrastructural phenotypes suggest active cell motility. The hypothesis that HB-GAM/N-syndecan interaction mediates osteoblast recruitment, as inferred from developmental studies, was tested using osteoblast-type cells that express N-syndecan abundantly. These cells migrate rapidly to HB-GAM in a haptotactic transfilter assay and in a migration assay where HB-GAM patterns were created on culture wells. The mechanism of migration is similar to that previously described for the HB-GAM-induced migratory response of neurons. Our hypothesis that HB-GAM/N-syndecan interaction participates in regulation of osteoblast recruitment was tested using two different in vivo models: an adjuvant-induced arthritic model and a transgenic model. In the adjuvant-induced injury model, the expression of HB-GAM and of N-syndecan is strongly upregulated in the periosteum accompanying the regenerative response of bone. In the transgenic model, the HB-GAM expression is maintained in mesenchymal tissues with the highest expression in the periosteum. The HB-GAM transgenic mice develop a phenotype characterized by an increased bone thickness. HB-GAM may thus play an important role in bone formation, probably by mediating recruitment and attachment of osteoblasts/osteoblast precursors to the appropriate substrates for deposition of new bone.

Neurite outgrowth in brain neurons induced by heparin-binding growth-associated molecule (HB-GAM) depends on the specific interaction of HB-GAM with heparan sulfate at the cell surface.

Heparin-binding growth-associated molecule (HB-GAM) is a cell-surface- and extracellular matrix-associated protein that lines developing axons in vivo and promotes neurite outgrowth in vitro. Because N-syndecan (syndecan-3) was found to function as a receptor in HB-GAM-induced neurite outgrowth, we have now studied whether the heparan sulfate side chains of N-syndecan play a role in HB-GAM-neuron interactions. N-Syndecan from postnatal rat brain was found to inhibit HB-GAM-induced but not laminin-induced neurite outgrowth when added to the assay media. The inhibitory activity was abolished by treating N-syndecan with heparitinase, but it was retained in N-syndecan-derived free glycosaminoglycan chains, suggesting that N-syndecan heparan sulfate at the cell surface is involved in HB-GAM-induced neurite outgrowth. Binding to HB-GAM and inhibition of neurite outgrowth was observed with heparin-related polysaccharides only; galactosaminoglycans were inactive. Significant inhibition of neurite outgrowth was induced by heparin and by N-syndecan heparan sulfate but not by heparan sulfates from other sources. A minimum of 10 monosaccharide residues were required for HB-GAM-induced neurite outgrowth. Experiments with selectively desulfated heparins indicated that 2-O-sulfated iduronic acid units, in particular, are of importance to the interaction with HB-GAM, were implicated to a lesser extent. Structural analysis of N-syndecan from 6-day-old rat brain indicated that the heparan sulfate chains contain sequences of contiguous, N-sulfated disaccharide units with an unusually high proportion (82%) of 2-O-sulfated iduronic acid residues. We suggest that this property of N-syndecan heparan sulfate is essential for HB-GAM binding and induction of neurite outgrowth.

HB-GAM is a cytokine present in Alzheimer's and Down's syndrome lesions.

The distribution of heparin binding growth associated molecule (HB-GAM) in the cerebral amyloidoses of Alzheimer's disease (AD) and Down's syndrome (DS), conditions characterized by the deposition of amyloid beta (A beta), was investigated immunohistochemically. Antibodies to HB-GAM, a cytokine which plays an important role in brain development and maturation, showed strong immunoreactivity with senile plaques in both AD and DS. Anti-HB-GAM reacted with pre-amyloid lesions, but only when markers of dystrophic neurites were present. The presence of HB-GAM in AD brains, but not in control brains, was confirmed by Western blotting. We suggest that the presence of HB-GAM in A beta lesions is a marker of neuronal injury.

Co-expression of heparin-binding growth-associated molecule (HB-GAM) and N-syndecan (syndecan-3) in developing rat brain.

Biochemical and cell biological studies have previously identified N-syndecan as a neuronal cell surface receptor in neurite outgrowth induced by heparin-binding growth-associated molecule (HB-GAM). In the present study we have compared temporal and spatial expression patterns of N-syndecan and HB-GAM using Northern and Western blotting and immunohistochemistry. Expression of N-syndecan mRNA and protein peaks during the perinatal developmental stage of the brain in the same manner as the expression of HB-GAM mRNA and protein. In addition, both proteins are preferentially localized to fiber tracts of developing brain. We suggest that HB-GAM and N-syndecan form ligand-receptor complexes in developing axon tracts of brain.

The role of heparin-binding growth-associated molecule (HB-GAM) in the postsynaptic induction in cultured muscle cells.

The heparan sulfate proteoglycan (HSPGs) is a components of the extracellular matrix of skeletal muscle that is concentrated at the neuromuscular junction (NMJ). Recent studies have suggested that HSPG, together with its bound peptide growth factors, plays important roles in autocrine or paracrine types of regulation of cell growth and differentiation. Heparin-binding growth-associated molecule (HB-GAM; also known as pleiotrophin, or p18) is a newly discovered HSPG-bound factor that is expressed at high levels in the developing CNS and PNS. In this study, we examined the role of this factor in NMJ development by examining its relationship to the formation of ACh receptor (AChR) clusters. Using an antibody against recombinant rat brain HB-GAM, we found that this protein is present prominently on the surface of cultured Xenopus myotomal muscle cells by immunocytochemistry. It is associated with HSPGs as evidenced by the fact that heparin and heparinase treatment greatly diminished the antibody labeling. HB-GAM is concentrated at preexisting AChR hot spots as well as at those induced by polystyrene beads. In addition, this molecule is also concentrated at AChR clusters induced by spinal cord neurons in nerve-muscle cocultures. To assess its function in synaptic induction, we applied recombinant HB-GAM-coated beads to cultured muscle cells to effect its focal presentation. Over 70% of these beads induced the formation of AChR clusters as shown by fluorescent alpha-bungarotoxin labeling. Furthermore, bath application of HB-GAM inhibited the nerve-induced formation of AChR clusters. Thus, HB-GAM is an endogenous muscle-derived factor that may be a component of the molecular mechanism in postsynaptic induction.

Expression of HB-GAM (heparin-binding growth-associated molecules) in the pathways of developing axonal processes in vivo and neurite outgrowth in vitro induced by HB-GAM.

HB-GAM (heparin-binding growth-associated molecule; p18) was previously isolated as a neurite outgrowth-promoting protein that is expressed at high levels in perinatal rat brain. cDNA cloning and expression revealed that HB-GAM is a novel secretory protein that is homologous with the retinoic acid-inducible MK protein. In the present paper we have used affinity-purified anti-peptide and anti-protein antibodies to study the expression of HB-GAM in the developing nervous system of the rat. In general, HB-GAM accumulates to extracellular structures that line growing axonal processes but is absent or only occurs at low levels in the axonal pathways after neurite extension has essentially ceased. During early stages of the nervous system development, HB-GAM is strongly expressed in the developing fiber tracts of the peripheral nervous system on embryonic days 12-14 (E12-E14). In the early central nervous system, HB-GAM is first expressed in a radial pattern along the neuroepithelial cells on E11-E12 and in early ascending neuron fibers in superficial layers of the brain vesicles on E12-E14. On E16-E18, HB-GAM is strongly expressed in the subplate and the marginal zone of the primordial neocortex. After this local expression in the primordial brain, HB-GAM is more widely expressed in the pathways of the developing axons during the late embryonic and early postnatal period. We have also extended in vitro studies on the interactions of HB-GAM with perinatal rat brain neurons by creating patterned substrates of HB-GAM upon culture wells and upon mixtures of extracellular matrix structures. These studies confirm the neurite-promoting effect of HB-GAM and suggest, together with the patterns of tissue localization, that HB-GAM may also guide axonal processes of brain neurons. The interactions of HB-GAM with brain neurons are specifically inhibited by heparin and its fragments and by incubation of the neurons with heparitinase. We suggest that in developing nervous tissues HB-GAM is deposited to an extracellular location in developing axon pathways and it interacts with heparin-like molecules of the neuron surface to promote formation of neural connections.

Isolation of a neuronal cell surface receptor of heparin binding growth-associated molecule (HB-GAM). Identification as N-syndecan (syndecan-3).

HB-GAM (heparin binding growth-associated molecule; pleiotrophin) is a secretory, extracellular matrix-associated protein that is strongly expressed in developing nervous tissues and belongs to a novel family of differentiation/growth factors. It promotes axonal growth from perinatal rat brain neurons and is suggested to be mitogenic for some cell types and to display cell-transforming activity. Since the receptors of HB-GAM in cells are unknown, we have started isolation of putative cell surface receptors from brain neurons and from perinatal rat brain. For this purpose, recombinant HB-GAM was produced with the aid of a baculovirus vector and used as an affinity matrix in receptor isolation. A detergent-solubilized component from cultured brain neurons and from brain was identified that binds specifically to HB-GAM and migrates on sodium dodecyl sulfate-polyacrylamide gel electrophoresis as a broad smear with an apparent molecular mass of about 200 kDa. This cell surface component was found to contain heparan sulfate chains, which are bound to a core protein with an apparent molecular mass of 120 kDa. Gel electrophoretic characteristics, immunochemical analysis, and partial peptide sequencing revealed that the cell surface component isolated as an HB-GAM receptor is N-syndecan (syndecan-3). In a solid phase binding assay, N-syndecan was found to bind to HB-GAM in a similar manner as to basic fibroblast growth factor (KD = 0.6 nM). Immunofluorescence microscopy indicated that in brain neurons, N-syndecan occurs at the surface of the cell soma and of the neurites that grow along HB-GAM-coated substrates. Anti-N-syndecan antibodies added to culture media had an inhibitory effect on HB-GAM-induced neurite outgrowth. We suggest that N-syndecan mediates the neurite outgrowth-promoting signal from HB-GAM to the cytoskeleton of growing neurites.

Amphoterin, the 30-kDa protein in a family of HMG1-type polypeptides. Enhanced expression in transformed cells, leading edge localization, and interactions with plasminogen activation.

Amphoterin is a heparin-binding protein that is developmentally regulated in brain and functionally involved in neurite outgrowth. Unexpectedly, amphoterin has a high mobility group 1 (HMG1)-type sequence. In the present study we have expressed amphoterin cDNA in a baculovirus vector and produced antibodies against the recombinant protein and several synthetic peptides. It was found that the amphoterin cDNA encodes the 30-kDa form of the protein isolated from tissues, whereas the co-purifying 28- and 29-kDa proteins (p28 and p29) have closely related but distinct primary structures. Partial amino acid sequencing shows several local changes in the sequences of p28 and p29 compared with amphoterin, suggesting the occurrence of a multigene family that encodes at least three different HMG1-type sequences in the rat. Studies using the probes that discern amphoterin from the other HMG1-type proteins indicate a high level expression in various transformed cell lines. Immunostaining of cells with the amphoterin-specific antibodies indicates a cytoplasmic localization that becomes remarkably enriched at the leading edges in spreading and motile cells. An extracellular localization is suggested by immunostaining of nonpermeabilized cells and by a plasminogen-dependent degradation of amphoterin in the substratum-attached material of cells. Tissue-derived and recombinant amphoterins strongly enhance the rate of plasminogen activation and promote the generation of surface-bound plasmin both by tissue-type and urokinase-type plasminogen activators. The results suggest an extracellular function for amphoterin in the leading edge of various invasive cells.

Secretion and biological activities of heparin-binding growth-associated molecule. Neurite outgrowth-promoting and mitogenic actions of the recombinant and tissue-derived protein.

The cDNA for the developmentally regulated, neurite outgrowth-promoting protein HB-GAM (heparin-binding growth-associated molecule) was recently cloned and shown to encode a novel lysine-rich sequence that is homologous with retinoic acid-induced sequences suggested to function in cell differentiation (Merenmies, J., and Rauvala, H. (1990) J. Biol. Chem. 265, 16721-16724). The same sequence was found for the mitogenic and neurite outgrowth-promoting protein pleiotrophin (Li, Y.-S., Milner, P. G., Chauhan, A. K., Watson, M. A., Hoffman, R. M., Kodner, C. M., Milbrandt, J., and Deuel, T. F. (1990) Science 250, 1690-1694). In this study, we have constructed a recombinant baculovirus using the cDNA that encodes the putative preprotein of HB-GAM. The putative secretion signal of HB-GAM is cleaved off in the baculovirus expression system, and the recombinant protein is rapidly secreted to the culture medium. Recombinant HB-GAM purified from the culture medium retains the biochemical characteristics and the neurite outgrowth-promoting activity found for the tissue-derived protein. Studies on the neurite outgrowth-promoting activity suggest that HB-GAM functions as an extracellular matrix-associated protein that enhances axonal growth in perinatal cerebral neurons of the rat. Since the same predicted amino acid sequence has been ascribed to a mitogenic protein, mitogenic activities of the recombinant HB-GAM and of tissue-derived HB-GAM fractions were also studied. Recombinant HB-GAM did not display any significant mitogenic activity, suggesting that tissue-derived HB-GAM preparations may contain other heparin-binding mitogenic factors. We identified in brain-derived HB-GAM fractions a 17-kDa protein (p17) that is detached from heparin by a slightly higher salt concentration as compared to HB-GAM. We suggest that p17 is structurally distinct from HB-GAM and responsible for the mitogenic actions of tissue-derived HB-GAM fractions.

Changes in lipid distribution and dynamics in degranulated rat liver rough endoplasmic reticulum due to the membrane attachment of polyribosomes.

Binding of rat liver polyribosomes to homologous degranulated rough endoplasmic reticulum (dRER) labeled with 10-(pyren-1-yl)decanoic acid (PDA) was studied. As a consequence of the membrane association of polysomes, the excimer/monomer fluorescence intensity ratios (Ie/Im) decreased, thus indicating alterations in the dynamics and organization of lipids. These fluorescence changes were complete within approximately 1 min, in accordance with the tight binding of ribosomes to RER. In order to characterize the changes in membrane lipid dynamics in more detail, polysomes were covalently labeled with trinitrobenzenesulfonic acid so as to allow their use as Förster-type resonance energy-transfer acceptors while utilizing PDA as a donor. Accordingly, assuming the binding of native and quencher-labeled ribosomes to the PDA-labeled membranes to be identical, we were able to discriminate fluorescence changes (a) in the proximity of the ribosome binding site from (b) those arising in the surrounding ribosome-free membrane and beyond the effective quenching radii of the TNP residues coupled to polysomes. Our data suggest that lipids in the polysome attachment site of dRER are less mobile than those in the remaining, ribosome-free membrane. In addition, there appears to be a relative enrichment of the PDA probe in the polyribosome membrane attachment sites.