Cell adhesion properties of myelin-associated glycoprotein in L cell fibroblasts

Nerve growth factor modulates myelin-associated glycoprotein binding to sensory neurons

Myelin-associated glycoprotein (MAG) is a molecule expressed by myelinating cells at the myelin/axon interface, which binds to an as yet unidentified molecule on neurons. We have used a MAG-immunoglobulin Fc fusion protein to examine the expression and regulation of the MAG binding molecule on sensory neurons in culture. Binding of the MAG-Fc reached a maximum at 24-48 h and was higher on neurons which expressed high levels of neurofilament. Nerve growth factor (NGF) upregulated expression of the MAG binding molecule in a dose dependent manner. Schwann cells co-cultured with sensory neurons in serum-free medium stimulated maximal expression of the MAG binding molecule, which was decreased by addition of anti-NGF to the co-cultures. This indicated that Schwann cells can modulate expression of the MAG binding molecule via production of NGF and may represent a physiological mechanism for regulation of MAG-MAG binding molecule interactions during myelination and remyelination.

MAG-deficient Schwann cells myelinate dorsal root ganglion neurons in culture

The myelin-associated glycoprotein (MAG) has been postulated to play a crucial role during myelin formation. Evidence supporting this hypothesis was provided by infecting rat Schwann cells with a retrovirus expressing MAG antisense RNA; these Schwann cells showed reduced levels of MAG expression and failed to myelinate DRG neurons in vitro. However, when MAG expression was disrupted by generating MAG-deficient mice, normal myelin sheaths were formed in peripheral nerves in vivo. In the present study we investigated whether myelination is compromised in MAG-deficient Schwann cells in vitro, i.e., under similar conditions where Schwann cells expressing MAG antisense RNA failed to myelinate. We show that MAG-deficient Schwann cells do myelinate DRG neurons in vitro and express the myelin-specific glycolipid galactocerebroside (Gal-C) and the myelin proteins P0 and MBP. Furthermore, myelin sheaths appear morphologically normal with both compacted and uncompacted aspects when investigated by electron microscopy. Quantitative analysis revealed that the number of myelin sheaths was similar in cultures from MAG-deficient and wild-type mice. These findings support the view that MAG is not essential for myelin formation in the PNS.

AvGp50, a predominantly axonally expressed glycoprotein, is a member of the IgLON's subfamily of cell adhesion molecules (CAMs)

We have previously reported a 50 kDa glycoprotein (AvGp50) expressed specifically in the chick nervous system [Hancox, K.A., Sheppard, A.M. and Jeffrey, P.L., Characterisation of a novel glycoprotein (AVGP50) in the avian nervous system, with a monoclonal antibody, Dev. Brain Res., 70 (1992) 25-37], and we present its molecular characterization. A PCR fragment was generated following sequencing of peptide and N-terminal fragments derived from purified AvGp50. A 1.58 kb clone (pUEX762) containing the 5'-UTR, the entire coding sequence and a short 3'-UTR was then isolated from a chick embryonic day 18 forebrain library. The deduced amino acid sequence encodes a 338 amino acid peptide containing a 31 amino acid signal peptide at the N-terminal and a 19 amino acid phosphatidylinositol glycan linkage sequence at the C-terminal. The mature protein contains three C2-immunoglobulin-like domains and a glycosyl phosphatidylinositol anchor and shares significant homology to other members of the immunoglobulin superfamily, including neural cell adhesion molecule (N-CAM), myelin-associated glycoprotein (MAG) and the Drosophila protein Amalgam. AvGp50 exhibits highest sequence identity to a recently classified subgroup of the immunoglobulin superfamily (IgLONs - immunoglobulin LAMP, OBCAM and neurotrimin - classified by Pimenta et al. [Pimenta, A.F., Zhukareva, V., Barbe, M.F., Reinoso, B.S., Grimley, C., Henzel, W., Fischer, I. and Levitt, P., The limbic system-associated membrane protein is an Ig superfamily member that mediates selective neuronal growth and axon targeting, Neuron, 15 (1995) 287-297], comprising the opioid binding cell adhesion molecule (OBCAM), neurotrimin and the limbic system-associated membrane protein (LAMP) suggesting that AvGp50 is a member of this subgroup. AvGp50 is expressed predominantly on the cell surface of axons, in particular Purkinje cell and granule cell axons in the cerebellum. In cerebellar and forebrain neuronal cultures, protein expression is exclusively located at the cell surface. Despite its cell surface localization, AvGp50 does not directly influence the outgrowth of neurons from explant cultures from ED8 to ED10 chick forebrain, prompting the suggestion that AvGp50 may act in later maturational events.

Differential intracellular sorting of the myelin-associated glycoprotein isoforms

Myelin-associated glycoprotein (MAG), a myelin-specific protein, is expressed as two isoforms, designated as L-MAG and S-MAG. Both share identical extracellular and transmembrane domains but differ in their cytoplasmic domains. L-MAG is expressed earlier during myelination than S-MAG. These features, as well as others, suggest that the isoforms have different functions. To confirm this hypothesis, both isoforms were expressed transiently and stably in Madin-Darby canine kidney (MDCK) epithelial cells, and the localization of the isoforms was studied. In both transiently and stably transfected cells, L-MAG sorted primarily to the basolateral membrane. In single transfected cells, S-MAG sorted primarily to the apical membrane. When groups of adjacent cells became transiently transfected, S-MAG accumulated at areas of cell-cell contact within the basolateral membrane. In stably transfected cells S-MAG sorted to the basolateral membrane. The data suggest that L-MAG contains an invariable basolateral sorting signal, but that the sorting of S-MAG is dependent upon extrinsic factors, such as coexpression by adjacent (contacting) cells. As MDCK cells sort the MAG isoforms differently, these data support the hypothesis that the MAG isoforms do perform different functions.

Myelin-associated glycoprotein: a role in myelination and in the inhibition of axonal regeneration?

Inhibitory molecules in CNS myelin affect axonal regeneration after injury. In the past year, myelin-associated glycoprotein (MAG), a well-characterized myelin protein, has been identified as an inhibitor of axonal regeneration. This finding, together with its established ability to promote outgrowth, defines MAG as a bifunctional molecule. MAG has also been included in a family of sialic acid binding proteins, providing a clue to the identity of the MAG receptor. MAG knockout mice reveal that MAG is not essential for the initiation of myelination; however, it plays an important role in maintaining a stable interaction between axons and myelin.

Intracellular transport and sorting of the oligodendrocyte transmembrane proteolipid protein

Delineating the properties and functions of the major central nervous system myelin proteins has been the focus of intensive research for decades. For PLP, this task has been confounded by its unusual properties, the complexity of the cellular membrane in which it resides, and the absence of a functional assay for the protein. The development of new experimental paradigms in which to study PLP may shed fresh light on the properties and functions of this intrinsic membrane protein. In the present communication we have used indirect, double label, immunofluorescence, and confocal microscopy to examine the distribution of PLP in Cos-7 cells transfected with an expression vector bearing the human PLP cDNA. Our results show that PLP is synthesized in the rough endoplasmic reticulum of transfected cells and passes through the Golgi apparatus to the cell surface. These results are consistent with previous studies showing PLP reaches the cell surface by transport through the secretory pathway. Levels of PLP at the cell surface are modest, most likely because protein deposited in this compartment can be endocytosed and subsequently transported to perinuclear lysosomes. Similar results are reported in the companion communication by Sinoway et al. (J Neurosci Res, 37:551-562, 1994). Using transfected HeLa cells they show that DM20 alone and PLP coexpressed with DM20 assume appropriate conformations for transport to the cell surface. The presence of PLP in subcellular compartments beyond the endoplasmic reticulum in Cos-7 cells indicates that the protein achieves a conformation appropriate for transport in the absence of other oligodendrocyte-specific factors; however, accumulation of large amounts of PLP in the cytoplasmic membrane compartment may require interactions with such glial-specific factors. Thus, the transfection paradigm described herein should prove a useful tool for investigating the folding and sorting of wild type and mutant forms of PLP as well as its membrane topology and posttranslational processing.

Myelination by mature ovine oligodendrocytes in vivo and in vitro: evidence that different steps in the myelination process are independently controlled

The ability of isolated mature post-myelination ovine oligodendrocytes to myelinate was investigated in tissue culture and in vivo. In culture, although the cells adhered preferentially to rat dorsal root ganglia (DRG) axons, sent out processes that encircled and wrapped them, proliferated, and synthesised myelin proteins (MBP), no myelination was found. This failure to find myelination occurred despite the fact that the oligodendrocytes both in the present experiments and in previous studies elaborated membranous structures that have been shown chemically and structurally to be similar to normal central nervous system myelin. These findings contrasted with those seen when neonatal rodent glial cells were added to similar DRG neuron cultures, in which myelination readily occurred. When the same adult ovine oligodendrocytes were transplanted into the brains of Shiverer mice, normal compact myelin was formed, proving that the cells were capable of myelination and suggesting that cross-species incompatibility was probably not a major factor in the lack of myelination in vitro. It is possible that the failure of ovine oligodendrocytes to myelinate DRG axons is due either to the relatively low number of supporting glial cells, such as astrocytes or microglia which may be necessary for satisfactory myelination, or that some other factor in the microenvironment is lacking; in any event, these results point to the complexity of oligodendrocyte-axon interactions. It is clear that each of the events, from adherence to proliferation to wrapping and the myelin compaction may be under the control of a different signal and may operate through a distinct mechanism, even though each process is dependent on the other. The results also point to the potential usefulness of this model system for deciphering such signals and mechanisms.

Immunoelectron microscopic localization of monoclonal IgM antibodies in gammopathy associated with peripheral demyelinative neuropathy

A sural nerve biopsy from a patient with benign monoclonal IgM kappa gammopathy and sensory-motor demyelinative neuropathy, revealed marked loss of myelinated fibers and focal axonal degeneration as well as widespread demyelination and remyelination with onion-skin formation. Almost all myelinated fibers displayed characteristic widening of the myelin lamellae as well as excessive thickness and/or exuberant outfoldings of myelin, reminiscent of that seen in tomaculous neuropathy. Many endoneurial capillaries were lined by fenestrated endothelium, indicating breakdown of a normal blood-nerve barrier. The endoneurium contained large amounts of extracellular proteinaceous material. Immunofluorescence and immunoelectron microscopy performed on the nerve of the patient, demonstrated selective deposition of IgM kappa gammaglobulin, exclusively in the areas of splittings of the myelin lamellae. Schwann cells contained cytoplasmic myelin debris labelled with IgM kappa only. In the indirect immunofluorescence and immunoelectron microscopy, serum of the patient reacted with the whole thickness of compact peripheral myelin of a normal human nerve. There was no immunoreactivity with the central myelin, Schwannoma cells, glial cells, axons or neurons. Demonstration of the selective presence of monoclonal IgM in widened lamellae of myelinated fibers, as well as bound to the internalized myelin debris in Schwann cells and macrophages, indicates a pathogenetic role of monoclonal paraprotein in myelin injury. Demyelination is promoted by development of endothelial fenestrations in the endoneurial capillaries and breakdown of the blood-nerve barrier.

The structure and function of central nervous system myelin

Multiple sclerosis (MS) is characterized by the active degradation of central nervous system myelin, a multilamellar membrane system that insulates nerve axons. MS arises from complex interactions between genetic, immunological, infective, and biochemical mechanisms. Although the circumstances of MS etiology remain hypothetical, one persistent theme involves immune system recognition of myelin-specific antigens derived from myelin basic protein, the most abundant extrinsic myelin membrane protein, and/or another equally suitable myelin protein or lipid. Knowledge of the biochemical and physical-chemical properties of myelin proteins, and lipids, particularly their composition, organization, structure, and accessibility with respect to the compacted myelin multilayers, thus becomes central to understanding how and why these antigens become selected during the development of MS. This article focuses on the current understanding of the molecular basis of MS as it may relate to the protein and lipid components of myelin, which dictate myelin morphology on the basis of protein-lipid and lipid-lipid interactions, and the relationship, if any, between the protein/lipid components and the destruction of myelin in pathological situations.

Homophilic and heterophilic binding activities of Nr-CAM, a nervous system cell adhesion molecule

Nr-CAM is a membrane glycoprotein that is expressed on neurons. It is structurally related to members of the N-CAM superfamily of neural cell adhesion molecules having six immunoglobulin-like domains and five fibronectin type III repeats in the extracellular region. We have found that the aggregation of chick brain cells was inhibited by anti-Nr-CAM Fab' fragments, indicating that Nr-CAM can act as a cell adhesion molecule. To clarify the mode of action of Nr-CAM, a mouse fibroblast cell line L-M(TK-) (or L cells) was transfected with a DNA expression construct encoding an entire chicken Nr-CAM cDNA sequence. After transfection, L cells expressed Nr-CAM on their surface and aggregated. Aggregation was specifically inhibited by anti-Nr-CAM Fab' fragments. To check the specificity of this aggregation, a fusion protein (FGTNr) consisting of glutathione S-transferase linked to the six immunoglobulin domains and the first fibronectin type III repeat of Nr-CAM was expressed in Escherichia coli. Addition of FGTNr to the transfected cells blocked their aggregation. Further analysis using a combination of cell aggregation assays, binding of cells to FGTNr-coated substrates, aggregation of FGTNr-coated Covaspheres and binding of FGTNr-coated Covaspheres to FGTNr-coated substrates revealed that Nr-CAM mediates two types of cell interactions: a homophilic, divalent cation-independent binding, and a heterophilic, divalent cation-dependent binding. Homophilic binding was demonstrated between transfected L cells, between chick embryo brain cells and FGTNr, and between Covaspheres to which FGTNr was covalently attached. Heterophilic binding was shown to occur between transfected and untransfected L cells, and between FGTNr and primary chick embryo fibroblasts; in all cases, it was dependent on the presence of either calcium or magnesium. Primary chick embryo glia or a human glial cell line did not bind to FGTNr-coated substrates. The results indicate that Nr-CAM is a cell adhesion molecule of the nervous system that can bind by two distinct mechanisms, a homophilic mechanism that can mediate interactions between neurons and a heterophilic mechanism that can mediate binding between neurons and other cells such as fibroblasts.

Gene expression in cells of the central nervous system

This review summarized a part of our studies over a long period of time, relating them to the literature on the same topics. We aimed our research toward an understanding of the genetic origin of brain specific proteins, identified by B. W. Moore and of the high complexity of the nucleotide sequence of brain mRNA, originally investigated by W. E. Hahn, but have not completely achieved the projected goal. According to our studies, the reason for the high complexity in the RNA of brain nuclei might be the high complexity in neuronal nuclear RNA as described in the Introduction. Although one possible explanation is that it results from the summation of RNA complexities of several neuronal types, our saturation hybridization study with RNA from the isolated nuclei of granule cells showed an equally high sequence complexity as that of brain. It is likely that this type of neuron also contains numerous rare proteins and peptides, perhaps as many as 20,000 species which were not detectable even by two-dimensional PAGE. I was possible to gain insight into the reasons for the high sequence complexity of brain RNA by cloning the cDNA and genomic DNA of the brain-specific proteins as described in the previous sections. These data provided evidence for the long 3'-noncoding regions in the cDNA of the brain-specific proteins which caused the mRNA of brain to be larger than that from other tissues. During isolation of such large mRNAs, a molecule might be split into a 3'-poly(A)+RNA and 5'-poly(A)-RNA. In the studies on genomic DNA, genes with multiple transcription initiation sites were found in brain, such as CCK, CNP and MAG, in addition to NSE which was a housekeeping gene, and this may contribute to the high sequence complexity of brain RNA. Our studies also indicated the presence of genes with alternative splicing in brain, such as those for CNP, MAG and NGF, suggesting a further basis for greater RNA nucleotide sequence complexity. It is noteworthy that alternative splicing of the genes for MBP and PLP also produced multiple mRNAs. Such a mechanism may be a general characteristic of the genes for the myelin-specific proteins produced by oligodendrocytes. In considering the high nucleotide sequence complexity, it is interesting that MAG and S-100 beta genes etc. possess two additional sites for poly(A).(ABSTRACT TRUNCATED AT 400 WORDS)