Tetraspanins are involved in Schwann cell-axon interaction.

Many studies have shown that tetraspanins play important role in cell-cell and cell-extracellular matrix (ECM) interactions. The repertoire and functions of tetraspanins in Schwann cells, glial cells of the peripheral nervous system have remained largely uncharacterized. This study was undertaken to identify Schwann cell tetraspanins and to elucidate their possible functions. Microarray analysis revealed the expression of numerous tetraspanins in primary culture of Schwann cells. Expression of five of them, CD9, CD63, CD81, CD82, and CD151, and of tetraspanin-associated protein EWI-2 was also confirmed by immunofluorescence. Localization of CD9, CD63, CD81, and EWI-2 was largely confined to paranodes and Schmidt-Lanterman incisures, regions of noncompact myelin. Immunoprecipitation experiments showed that these four proteins form a complex in Schwann cells. siRNA silencing of individual components of the complex did not affect Schwann cell adhesion to ECM proteins or attachment to and alignment with axons. However, suppression of both CD63 and CD81 expression together significantly inhibited extension of Schwann cell processes along axons, without affecting initial attachment of the cells to the axonal surface. Adhesion, spreading, and migration of Schwann cells on ECM proteins also were not affected by double silencing of CD63 and CD81. Suppression of CD63 and CD81 expression did not affect the ability of Schwann cells to myelinate dorsal root ganglion neurons in vitro. These findings strongly suggest that CD63 and CD81 play an important role in Schwann cell spreading along axons but seem to be dispensable for Schwann cell myelination.

Novel pathways in the pathobiology of human abdominal aortic aneurysms.

OBJECTIVES: Abdominal aortic aneurysm (AAA), a dilatation of the infrarenal aorta, typically affects males >65 years. The pathobiological mechanisms of human AAA are poorly understood. The goal of this study was to identify novel pathways involved in the development of AAAs. METHODS: A custom-designed 'AAA-chip' was used to assay 43 of the differentially expressed genes identified in a previously published microarray study between AAA (n = 15) and control (n = 15) infrarenal abdominal aorta. Protein analyses were performed on selected genes. RESULTS: Altogether 38 of the 43 genes on the 'AAA-chip' showed significantly different expression. Novel validated genes in AAA pathobiology included ADCY7, ARL4C, BLNK, FOSB, GATM, LYZ, MFGE8, PRUNE2, PTPRC, SMTN, TMODI and TPM2. These genes represent a wide range of biological functions, such as calcium signaling, development and differentiation, as well as cell adhesion not previously implicated in AAA pathobiology. Protein analyses for GATM, CD4, CXCR4, BLNK, PLEK, LYZ, FOSB, DUSP6, ITGA5 and PTPRC confirmed the mRNA findings. CONCLUSION: The results provide new directions for future research into AAA pathogenesis to study the role of novel genes confirmed here. New treatments and diagnostic tools for AAA could potentially be identified by studying these novel pathways.

Fibrillin-2 is dispensable for peripheral nerve development, myelination and regeneration.

The extracellular matrix of peripheral nerve is formed from a diverse set of macromolecules, including glycoproteins, collagens and proteoglycans. Recent studies using knockout animal models have demonstrated that individual components of the extracellular matrix play a vital role in peripheral nerve development and regeneration. In this study we identified fibrillin-1 and fibrillin-2, large modular structural glycoproteins, as components of the extracellular matrix of peripheral nerve. Previously it was found that fibrillin-2 null mice display joint contractures, suggesting a possible defect of the peripheral nervous system in these animals. Close examination of the peripheral nerves of fibrillin-2 deficient animals described here revealed some structural abnormalities in the perineurium, while general structure of the nerve and molecular composition of nerve extracellular matrix remained unchanged. We also found that in spite of the obvious motor function impairment, fibrillin-2 null mice failed to display changes of nerve conduction properties or nerve regeneration capacity. Based on the data obtained we can conclude that peripheral neuropathy should be excluded as the cause of the impairment of locomotory function and joint contractures observed in fibrillin-2 deficient animals.

Regulation of Schwann cell function by the extracellular matrix.

Laminins and collagens are extracellular matrix proteins that play essential roles in peripheral nervous system development. Laminin signals regulate Schwann cell proliferation and survival as well as actin cytoskeleton dynamics, which are essential steps for radial sorting and myelination of peripheral axons by Schwann cells. Collagen and their receptors promote Schwann cell adhesion, spreading, and myelination as well as neurite outgrowth. In this article, we will review the recent advances in the studies of laminin and collagen function in Schwann cell development.

Fibronectin fibrillogenesis regulates three-dimensional neovessel formation.

During vasculogenesis and angiogenesis, endothelial cell responses to growth factors are modulated by the compositional and mechanical properties of a surrounding three-dimensional (3D) extracellular matrix (ECM) that is dominated by either cross-linked fibrin or type I collagen. While 3D-embedded endothelial cells establish adhesive interactions with surrounding ligands to optimally respond to soluble or matrix-bound agonists, the manner in which a randomly ordered ECM with diverse physico-mechanical properties is remodeled to support blood vessel formation has remained undefined. Herein, we demonstrate that endothelial cells initiate neovascularization by unfolding soluble fibronectin (Fn) and depositing a pericellular network of fibrils that serve to support cytoskeletal organization, actomyosin-dependent tension, and the viscoelastic properties of the embedded cells in a 3D-specific fashion. These results advance a new model wherein Fn polymerization serves as a structural scaffolding that displays adhesive ligands on a mechanically ideal substratum for promoting neovessel development.

Alpha7beta1 integrin is a receptor for laminin-2 on Schwann cells.

The Schwann cell basal lamina acts as an organizer of peripheral nerve tissue and influences many aspects of cell behavior during development and regeneration. A principal component of the Schwann cell basal lamina is laminin-2. This study was undertaken to identify Schwann cell receptors for laminin-2. We found that among several Schwann cell integrins that can potentially interact with laminin-2, only alpha7beta1 bound to laminin-2-Sepharose. Dystroglycan, a non-integrin Schwann cell receptor for laminin-2 identified previously, was also found to bind to laminin-2-Sepharose. Antibody to the alpha7 integrin subunit partially inhibited Schwann cell adhesion to laminin-2. Small interfering RNA-mediated suppression of either alpha7 integrin or dystroglycan expression decreased adhesion and spreading of Schwann cells on laminin-2, whereas knocking down both proteins together inhibited adhesion and spreading on laminin-2 almost completely. alpha7 integrin and dystroglycan both colocalized with laminin-2 containing basal lamina tubes in differentiating neuron-Schwann cell cocultures. The alpha7beta1 integrin also coprecipitates with focal adhesion kinase in differentiating cocultures. These findings strongly suggest that alpha7beta1 integrin is a Schwann cell receptor for laminin-2 that provides transmembrane linkage between the Schwann cell basal lamina and cytoskeleton.

Glypican-1 and alpha4(V) collagen are required for Schwann cell myelination.

Schwann cell myelination requires interactions with the extracellular matrix (ECM) mediated by cell surface receptors. Previously, we identified a type V collagen family member, alpha4(V) collagen, which is expressed by Schwann cells during peripheral nerve differentiation. This collagen binds with high affinity to heparan sulfate through a unique binding motif in the noncollagenous N-terminal domain (NTD). The principal alpha4(V) collagen-binding protein on the Schwann cell surface is the heparan sulfate proteoglycan glypican-1. We investigated the role of alpha4(V) collagen and glypican-1 in Schwann cell terminal differentiation in cultures of Schwann cells and dorsal root ganglion neurons. Small interfering RNA-mediated suppression of glypican-1 expression decreased binding of alpha4(V)-NTD to Schwann cells, adhesion and spreading of Schwann cells on alpha4(V)-NTD, and incorporation of alpha4(V) collagen into Schwann cell ECM. In cocultures, alpha4(V) collagen coassembles with laminin on the surface of polarized Schwann cells to form tube-like ECM structures that are sites of myelination. Suppression of glypican-1 or alpha4(V) collagen expression significantly inhibited myelination. These results demonstrate an important role for these proteins in peripheral nerve terminal differentiation.

alphaVbeta8 integrin is a Schwann cell receptor for fibrin.

The interaction of Schwann cells with molecules in the extracellular environment following peripheral nerve injury is a critical aspect of nerve repair. A principal component of this material is fibrin, which derives from fibrinogen infiltrating into the nerve after the injury. This study was undertaken to identify cell surface receptor(s) that mediate the interaction of Schwann cells with fibrin. We found that adhesion of Schwann cells to fibrin could be effectively inhibited by low concentrations of RGD-containing peptides. Among RGD-sensitive integrins expressed by Schwann cell, alphaVbeta8, but not alpha5beta1, was found to bind to fibrin-Sepharose. In contrast, both of these integrins bound to fibronectin-Sepharose. We also found that alphaV, but not alpha5 or beta1 integrin subunit, accumulated in focal contacts of Schwann cell plated on fibrin. Taken together, these results strongly suggest that alphaVbeta8 integrin is a Schwann cell receptor for fibrin.

Schwann cell adhesion to a novel heparan sulfate binding site in the N-terminal domain of alpha 4 type V collagen is mediated by syndecan-3.

Previously we reported that type V collagen synthesized by Schwann cells inhibits the outgrowth of axons from rat embryo dorsal root ganglion neurons but promotes Schwann cell migration (Chernousov, M. A., Stahl, R. C., and Carey, D. J. (2001) J. Neurosci. 21, 6125-6135). Analysis of Schwann cell adhesion and spreading on dishes coated with various type V collagen domains revealed that Schwann cells adhered effectively only to the non-collagenous N-terminal domain (NTD) of the alpha4(V) collagen chain. Schwann cell adhesion to alpha4(V)-NTD induced actin cytoskeleton assembly, tyrosine phosphorylation, and activation of the Erk1/Erk2 protein kinases. Adhesion to alpha4(V)-NTD is cell type-specific because rat fibroblasts failed to adhere to dishes coated with this polypeptide. Schwann cell adhesion and spreading on alpha4(V)-NTD was strongly inhibited by soluble heparin (IC(50) approximately 30 ng/ml) but not by chondroitin sulfate. Analysis of the heparin binding activities of a series of recombinant alpha4(V)-NTD fragments and deletion mutants identified a highly basic region (not present in other type V collagen NTD) as the site responsible for high affinity heparin binding. Schwann cells adhered poorly to dishes coated with alpha4(V)-NTD that lacked the heparin binding site and failed to spread or assemble organized actin-cytoskeletal structures. Soluble alpha4(V)-NTD polypeptide that contained the heparin binding site inhibited spreading of Schwann cells on dishes coated with alpha4(V)-NTD. Affinity chromatography of Schwann cell detergent extracts on a column of immobilized alpha4(V)-NTD resulted in the isolation of syndecan-3, a transmembrane heparan sulfate proteoglycan. Together, these results suggest that Schwann cells bind to collagen type V via syndecan-3-dependent binding to a novel high affinity heparin binding site in the alpha4(V)-NTD.