Anti-β1 integrin antibody inhibits schwann cell meylination

Schwann cells (SCs) co-cultured with sensory neurons require ascorbate supplementation for basal lamina assembly and differentiation into myelinating cells. The ascorbate requirement can be bypased by adding a purifed basal lamina component, laminin, to SC/neuron cocultures. We have examined the role of laminin receptors, Namely, the β1 subfamily of integrins, in the process of myelination. We demonstrate by immunostaining or immunoprecipitation that undifferentiated SCs in contact with axons express large amounts of the β1 subunit in association with the α1 or α6 subunit. In co-cultures of myelinating SCs, α1β1 is no longer present, α6β1 is still present but at reduced levels, and α6β4 is expressed at much higher levels than in co-cultures of undifferentiated SCs. Immunogold labelling at the electron microscope level suggested that β1 integrins are randomly distributed on undifferentiated SCs, become localized to the SC surface contacting basal lamina in differentiating SCs before the onset of myelination, and are not detected on myelinating SCs. Fab fragments of β1 function-blocking antibody block both attachment of isolated SCs to laminin and formation of myelin sheaths by SCs co-cultured with neurons in ascorbate-supplemented medium. SCs unable to myelinate in the presence of the anti-β1 antibody assemble patchy basal lamina that is only loosely attached to the cell surface and in some cases appears to be detaching from the membrane. In contrast, an α1β1 function-blocking antibody only partially blocks attachment of isolated SCs to laminin but has no inhibitory effect on SC myelination. These results are consistent with the hypothesis that a member of the β1 subfamily of integrins other than α1β1 binds laminin present in basal lamina to the SC surface and transduces signals that are critical for initiation of SC differentiation into a myelinating cell. 1994 John Wiley & Sons, Inc.     

Basal lamina: Schwann cells wrap to the rhythm of space-time

Schwann cells form myelin in the peripheral nervous system. All Schwann cells are surrounded by a basal lamina. Extracellular matrix molecules in the basal lamina, such as laminin, regulate key aspects of Schwann cell development including the formation, architecture and function of myelin. Recent genetic and cell biological experiments suggest that Schwann cells regulate the basal lamina and its receptors in both time and space, resulting in differential functions. These findings have important implications for diseases resulting from laminin dysfunction, such as congenital muscular dystrophy 1A.     

Role of basal lamina in Schwann cell glycolipid biosynthesis

Schwann cells that are deprived of axonal contact switch their glycolipid metabolic pathway from primarily galactocerebroside (GalCe) synthesis to the formation of glucocerebroside (GlcCe) and its homologs. The removal of axonal influence has a dual effect on Schwann cell phenotype; they lose the ability to assemble both myelin and basement membrane. To determine whether a loss of basement membrane directly affects glycolipid expression, we have examined lipid biosynthesis in Schwann cells which were allowed to interact with axons of dorsal root ganglion neurons but which were deprived of the ability to assemble basal lamina. These Schwann cells resemble those from myelinating nerve in that they synthesize a large amount of galactohydroxycerebroside. This suggests that axon contact, even in the absence of basement membrane, is sufficient to induce the GalCe metabolic pathway.Abbreviations DRG dorsal root ganglia - GalCe galactocerebroside - GalCe-OH galactohydroxycerebroside - GlcCe glucocerebroside - GL-2 lactosylceramide - GL-3 trihexosylceramide - GL-4 tetrahexosylceramide - HPTLC high-performance thin-layer chromatography - MGDG monogalactosyl diacylglycerol - NL non-polar lipids - PC phosphatidylcholine - Su sulfatide - Su-OH hydroxysulfatide     

Schwann cells infected with a recombinant retrovirus expressing myelin-associated glycoprotein antisense RNA do not form myelin.

To elucidate the role of myelin-associated glycoprotein (MAG) in the axon-Schwann cell interaction leading to myelination, neonatal rodent Schwann cells were infected in vitro with a recombinant retrovirus expressing MAG antisense RNA or MAG sense RNA. Stably infected Schwann cells and uninfected cells were then cocultured with purified sensory neurons under conditions permitting extensive myelination in vitro. A proportion of the Schwann cells infected with the MAG antisense virus did not myelinate axons and expressed lower levels of MAG than control myelinating Schwann cells, as measured by immunofluorescence. Electron microscopy revealed that the affected cells failed to segregate large axons and initiate a myelin spiral despite having formed a basal lamina, which normally triggers Schwann cell differentiation. Cells infected with the MAG sense virus formed normal compact myelin. These observations strongly suggest that MAG is the critical Schwann cell component induced by neuronal interaction that initiates peripheral myelination.     

Characterization of osteoblastic differentiation of stromal cell line ST2 that is induced by ascorbic acid

The stromal cell line ST2, derived from mouse bone marrow,differentiated into osteoblast-like cells in response to ascorbic acid.Ascorbic acid induced alkaline phosphatase (ALPase) activity, theexpression of mRNAs for proteins that are markers of osteoblastic differentiation, the deposition of calcium, and the formation ofmineralized nodules by ST2 cells. We investigated the mechanism wherebyascorbic acid induced the differentiation of ST2 cells. Inhibitors ofthe formation of collagen triple helices completely blocked the effectsof ascorbic acid on ST2 cells, an indication that matrix formation bytype I collagen is essential for the induction of osteoblasticdifferentiation of ST2 cells by ascorbic acid. We furthermore examinedthe effects of bone morphogenetic proteins (BMPs) on thedifferentiation of ST2 cells induced by ascorbic acid. Ascorbic acidhad no effect on the expression of mRNAs for BMP-4 and the BMPreceptors. However, a soluble form of BMP receptor IAinhibited the induction of ALPase activity by ascorbic acid. Theseresults suggest that ascorbic acid might promote the differentiation ofST2 cells into osteoblast-like cells by inducing the formation of amatrix of type I collagen, with subsequent activation of the signalingpathways that involve BMPs.

     

Expression of Myelin Components in Mouse Schwann Cells in Culture

Mouse Schwann cells cultured in vitro are capable of expressing basal levels of the major myelin components P1, P2, P0, and galactocerebroside. Numerical counts of immunostained cultures indicated that between 22 and 40% of the cells are positive up to 21 days for all of the components indicated. Electrophoretic analysis of Schwann cells labeled with a 14C-amino acid mixture revealed the presence of proteins with relative mobilities identical to those of P0 and P1. Positive identification of the two proteins was indicated by immunoprecipitation of P1 and immunoblotting of P0. These data show that in the absence of neurites, Schwann cells in culture can express low levels of myelin characteristic components even in the absence of myelin assembly.     

Neuron-schwann cell interaction in basal lamina formation

The availability of tissue culture systems that allow the growth of nerve cells, Schwann cells, and fibroblasts separately or in various combinations now makes possible investigation of the role of cell interactions in the development of the peripheral nervous system. Using these systems it was earlier found that basal lamina is formed on the Schwann cell surface in cultures of sensory ganglion cells and Schwann cells without fibroblasts. It is here reported that the presence of nerve cells is required for the generation of basal lamina on the Schwann cell plasmalemma. Utilizing nerve cell-Schwann cell preparations devoid of fibroblasts, this was found in the following ways. (1) When nerve cells are removed from 3- to 5-week-old cultures, the basal lamina disappears from Schwann cells. (2) If nerve cells are added back to such Schwann cell populations, Schwann cell basal lamina reappears. (3) Removal of nerve cells from older (3–4 months) cultures does not lead to basal lamina loss; areas presumed not to have been coated with lamina before neurite degeneration remain so, suggesting that the lamina persists but is not reformed. (4) If basal lamina is removed with trypsin, it is reformed in neuron plus Schwann cell cultures but not in Schwann cell populations alone. Thus, the formation but not the persistence of Schwann cell basal lamina requires the presence of nerve cells.     

Ultrastructural localization of laminin in rat sensory ganglia

We adapted immunocytochemical methods for localization of laminin to examine its disposition in neural tissue at the ultrastructural level. In dorsal root ganglia, laminin was found in basal laminae of the satellite and Schwann cells ensheathing neuronal perikarya and nerve fibers, respectively, and around blood vessels. Within the basal lamina, the immunostain was found in the lamina lucida and lamina densa. Occasional immunostained coated pits were identified in satellite and Schwann cells, but virtually no intracellular label was seen even in freeze-thawed/detergent-permeabilized specimens. In the perineurium, only the basal lamina of the inward-facing surface of the inner-most cell layer was usually stained.     

Myelination in coculture of established neuronal and Schwann cell lines

Establishing stable coculture systems with neuronal and Schwann cell lines has been considered difficult, presumably because of their high proliferative activity and phenotypic differences from primary cultured cells. The present study is aimed at developing methods for myelin formation under coculture of the neural crest-derived pheochromocytoma cell line PC12 and the immortalized adult rat Schwann cell line IFRS1. Prior to coculture, PC12 cells were seeded at low density (3 × 10(2)/cm(2)) and maintained in serum-free medium with N2 supplement, ascorbic acid (50 μg/ml), and nerve growth factor (NGF) (50 ng/ml) for a week. Exposure to such a NGF-rich environment with minimum nutrients accelerated differentiation and neurite extension, but not proliferation, of PC12 cells. When IFRS1 cells were added to NGF-primed PC12 cells, the cell density ratio of PC12 cells to IFRS1 cells was adjusted from 1:50 to 1:100. The cocultured cells were then maintained in serum-free medium with B27 supplement, ascorbic acid (50 μg/ml), NGF (10 ng/ml), and recombinant soluble neuregulin-1 type III (25 ng/ml). Myelin formation was illustrated by light and electron microscopy performed at day 28 of coculture. The stable PC12-IFRS1 coculture system is free of technical and ethical problems arising from the primary culture and can be a valuable tool to study peripheral nerve degeneration and regeneration.     

Ascorbic Acid in Mesencephalic Cultures: Effects on Dopaminergic Neuron Development

Ascorbic acid exists in high intracellular concentrations in fetal rat brain. In mesencephalic cultures the cellular ascorbic acid content drops sharply to undetectable levels when no ascorbic acid is added to the medium, thus creating a model of scorbutic neuronal tissue and affording the study of ascorbic acid's effects on mesencephalic cell development and function. Cultures treated with 0.2 mM ascorbic acid were compared with controls (scorbutic cultures) by using morphological and biochemical indices. Ascorbic acid cultures at 7 and 14 days in vitro showed a marked increase in glial proliferation on glial fibrillary acidic protein staining and increased neurite growth and number on tyrosine hydroxylase staining. Significantly higher dopamine uptake and levels of dopamine and 3,4-dihydroxyphenylacetic acid were also observed after 7 and 14 days of ascorbic acid treatment. The capacity to accumulate ascorbic acid and the ability to retain the intracellular ascorbic acid developed gradually as the cultures matured. Ascorbic acid reached the embryonal levels by day 14 in vitro. We conclude that although neuronal cultures can survive and grow in the absence of detectable levels of ascorbic acid, its presence exerts a broad effect on dopamine neuron morphology and biochemical functioning either directly or through increased glial proliferation, or possibly both.     

Basal lamina formation by epithelial cell lines correlates with laminin A chain synthesis and secretion.

Laminin is a major component of the basal lamina upon which all epithelial cells reside in vivo. The synthesis of basal lamina components and their subsequent assembly into a morphologically distinct basal lamina is a differentiated function of epithelial cells in vivo. Ultrastructural studies in our laboratory show that some epithelial cell lines (P-MDCK) form a basal lamina when cultured on membrane-permeable substrate (Millipore Millicells or type I collagen gels). Under the same conditions other epithelial cell lines (MDCK-AA7, M-mTAL-1P, and T84) do not form a basal lamina. When metabolically labeled with [35S]methionine, laminin A and B chains can be immunoprecipitated from the culture medium and culture lysates of P-MDCK cells. In contrast, labeled laminin chains cannot be immunoprecipitated from the culture medium of MDCK-AA7, M-mTAL-1P, and T84 cells. Immunoprecipitates of MDCK-AA7, M-mTAL-1P, and T84 culture lysates demonstrate the presence of one or both B chains but not A chains. These results suggest that laminin B chain synthesis is constitutive in MDCK-AA7, M-mTAL-1P, and T84 cells and that B chains, in the absence of A chains, are not secreted. Furthermore, laminin secretion and basal lamina formation are not required to maintain structural and functional polarity in these cell lines.     

Characterization of human nerve basal lamina for their binding properties of anti-MAG antibodies

The functional importance of the basal lamina in Schwann cell development and in adult peripheral nerve fibers is well known. We have demonstrated previously by confocal microscopy that IgM deposits are present on the basal lamina of myelinating Schwann cells of nerve biopsies from patients with an anti-MAG IgM neuropathy. Therefore, the basal lamina was postulated to represent an early target for the uptake of autoantibodies on the surface of myelinated nerve fibers. In this study, the preparation of cell- and myelin-free basal lamina from human peripheral nerves, using a detergent-dependent method is described and characterized by immunohistochemical and biochemical analysis. Using these methods we demonstrated that an enrichment of basal lamina components of Schwann cells with extraction of myelin could be achieved. Western blot analysis and immunohistochemical characterization showed that anti-MAG IgM antibodies did not recognize an epitope on the basal lamina of normal nerves. The established method will allow in situ investigations of basal lamina components from human peripheral nerves in health and in disease, e.g. peripheral neuropathies of infectious or inflammatory origin.     

Enhancement of chemotactic response and microtubule assembly in human leukocytes by ascorbic acid.

The incubation of human leukocytes with ascorbic acid increased chemotaxis of the cells. In addition, ascorbic acid promoted the assembly of intracellular polymorphonuclear leukocyte (PMN) with colchicine blocked the effect of ascorbic acid on promoting microtubule assembly. Not only did ascorbic acid promote the assembly of microtubules in vivo, but it enhanced the assembly of bovine brain tubulin into microtubules in vitro as quantitated by a glass-fiber filtration assay and by promotion of viscosity changes. The enhancement in leukocyte mobility by ascorbate at concentrations achievable in normal tissues correlates with its ability to assemble microtubule organelles.     

Migratory behavior of cells on embryonic retina basal lamina

In order to study cell translocation in vitro on a physiological substrate a novel cell migration assay was developed using the inner limiting membrane of the avian embryonic retina. The matrix sheet consists of a laminin-rich basal lamina covered by a dense layer of neuroepithelial endfeet. The retina basal lamina does not contain fibronectin. Cells translocating on this substrate displace the neuroepithelial endfeet, leaving behind tracks in the endfeet monolayer. Motility of cells and the relative forward to lateral migration can be quantitated by measuring lengths, widths, and areas of the tracks. Using this assay system, the conditions and patterns of cell migration for a variety of cells have been examined. In the absence of serum all cell types show only minor migratory activity and addition of serum to the culture medium always enhances the rate of cell migration in a saturable, dose-response manner. The serum cannot be replaced by fibronectin or vitronectin (serum spreading factor). For maximum cell migration, serum has to be constantly present in the medium; however, 58% cell migration is obtained in serum-free medium when the matrix is preincubated with serum. According to the area and linearity of the tracks, the migratory behavior of the different cells can be classified into three groups: (i) fibroblasts and the nonpigmented Bowes melanoma cells form straight and long tracks; (ii) glioma, sarcoma, and carcinoma cells from straight but short tracks, and (iii) neuronal tumor cells, epithelial cells, and pigmented B16 melanoma cells form wide and short tracks. Comparative studies with low and high metastatic clones of tumorgenic cell lines show that migratory activity and metastatic potential of cells do not necessarily correlate. Finally, we show that fibroblasts deposit fibronectin fibrils on their paths as they migrate on the basal lamina. Fibronectin trails are also seen when fibroblasts are cultured on plain basal laminae that are pretreated with detergent to remove the endfeet monolayer. Likewise, when fibroblasts are cultured in the presence of antifibronectin antibodies, the fibronectin secreted by cells is detectable. Due to antibody treatment the cellular fibronectin is precipitated and its normal fibril formation is inhibited; however, the translocation of fibroblasts is not impaired.     

Nf1-deficient mouse Schwann cells are angiogenic and invasive and can be induced to hyperproliferate: reversion of some phenotypes by an inhibitor of farnesyl protein transferase.

We have developed a potential model of Schwann cell tumor formation in neurofibromatosis type 1 (NF1). We show that mouse Schwann cells heterozygous or null at Nf1 display angiogenic and invasive properties, mimicking the behavior of Schwann cells from human neurofibromas. Mutations at Nf1 are insufficient to promote Schwann cell hyperplasia. Here we show that Schwann cell hyperplasia can be induced by protein kinase A activation in mutant cells. Removal of serum from the culture medium also stimulates hyperplasia, but only in some mutant cells. After serum removal, clones of hyperproliferating Schwann cells lose contact with axons in vitro, develop growth factor-independent proliferation, and exhibit decreased expression of the cell differentiation marker P0 protein; hyperproliferating cells develop after a 1-week lag in Schwann cells heterozygous at Nf1. The experiments suggest that events subsequent to Nf1 mutations are required for development of Schwann cell hyperplasia. Finally, an anti-Ras farnesyl protein transferase inhibitor greatly diminished both clone formation and hyperproliferation of null mutant cells, but not invasion; farnesyl transferase inhibitors could be useful in treating benign manifestations of NF1.     

Biosynthesis of type IV collagen by cultured rat Schwann cells

We have obtained evidence that rat Schwann cells synthesize and secrete type IV procollagen. Metabolic labeling of primary cultures of Schwann cells plus neurons and analysis by SDS PAGE revealed the presence of a closely spaced pair of polypeptides in the medium of these cultures that (a) were susceptible to digestion by purified bacterial collagenase, (b) co-migrated with type IV procollagen secreted by rat parietal endoderm cells, and (c) were specifically immunoprecipitated by antibodies against mouse type IV collagen. Limited pepsin digestion of metabolically labeled medium or cell layers produced a pepsin- resistant fragment characteristic of pro-alpha 1(IV) chains. Removal of neuronal cell bodies from the cultures immediately before labeling did not reduce the amount of type IV procollagen detected in the medium. This indicated that Schwann cells, not neurons, were responsible for synthesis of type IV procollagen. We believe type IV procollagen is a major constituent of the Schwann-cell extracellular matrix based upon (a) its presence in a detergent-insoluble matrix preparation, (b) its presence in the cell layer of the cultures in a state in which it can be removed by brief treatment with bacterial collagenase or trypsin, and (c) positive immunofluorescence of Schwann cell-neuron cultures with anti-type-IV collagen antibodies. Secretion of type IV procollagen was substantially reduced when Schwann cells were maintained in the absence of neurons. This observation may account for the previously reported finding that Schwann cells assemble a basal lamina only when co-cultured with neurons (Bunge, M. B., A. K. Williams, and P. M. Wood, 1982, Dev. Biol., 92:449).     

Basal lamina of embryonic salivary epithelia. Nature of glycosaminoglycan and organization of extracellular materials

The ultrastructural organization and the composition of newly synthesized glycosaminoglycan (GAG) in the epithelial basal lamina of mouse embryo submandibular glands were assessed. The labeled GAG accumulating in the lamina is distinct from that in its tissue of origin, the epithelium, or from that in the surrounding mesenchyme. In the lamina, hyaluronic acid accounts for approximately 50% of the labeled GAG, chondroitin-4-sulfate is twice the chondroitin-6-sulfate, and there is a low proportion of chondroitin. This composition is constant regardless of whether the lamina is labeled by whole glands or, in the absence of mesenchyme, by isolated epithelia retaining a lamina and by isolated epithelia generating a lamina de novo. The results andicate that the labeled GAG are bona fide components of the lamina, and suggest that laminar GAG is deposited in units of constant composition. Ultrastructural observations following ruthenium red staining or tannic acid fixation extablish that the lamina is a highly ordered specialization of the basal cell surface. Discrete structures in macroperiodic arrays apparently attached to the plasmalemma are visualized. This organization is seen in intact glands and in the laminae produced by epithelia in the absence of mesenchyme or biological substrate. The data are interpreted as indicating that the basal lamina contains supramolecular complexes of hyaluronic acid and proteoglycan which are organized into an extracellular scaffolding which imposes structural form on the epithelium.