Role of astrocytes in antigen presentation and naive T-cell activation.

Astrocytes may have a role in antigen presentation in inflammatory diseases of the central nervous system (CNS) such as MS and EAE. In this study, we have assessed whether purified astrocyte cultures could stimulate naive CD4(+) or CD8(+) T-cells from TCR transgenic mice. As previously described, astrocytes sustained antigen-specific CD4(+) T-cell proliferation only in the presence of IFN-gamma, which promotes expression of both MHC class II and B7 molecules on astrocytes. In addition, we show that astrocytes also have the capacity to present antigens to naive CD8(+) T-cell and promote their proliferation. In one system, this CD8(+) T-cell proliferation was dependent on IFN-gamma-induced upregulation of B7 molecules on astrocytes. However, in a second TCR transgenic system, astrocytes could induce naive CD8(+) T-cell proliferation even in the absence of IFN-gamma. The possible implications of these findings for the pathophysiology of CNS inflammatory diseases are discussed.

Biotinylated derivative of a human brain lectin: synthesis and use in affinoblotting for endogenous ligand studies.

Coupling of biotin to an endogenous lectin yields a probe which can be used for selective nonradioactive detection of complementary endogenous ligands. To exemplify practical applications of this type of compounds, we have synthesized and characterized a biotinylated derivative of a beta-galactoside-specific human brain lectin. Proteins which bind this lectin can be located on nitrocellulose sheets after electrophoretic transfer from gradient polyacrylamide gels, by sequential incubation with biotinylated probes and streptavidin-peroxidase, with visualization by an insoluble reaction product (affinoblotting). Biotinylated galactoside-binding plant lectins were used in the same way to visualize human brain glycoproteins, and their binding specificity was compared with that of human brain lectin. The results obtained by means of these different probes showed the usefulness of the endogenous lectin derivative to actually identify its endogenous partners. Thus this approach may find extended applications in the study of biological activities of vertebrate lectins in homologous systems, i.e., with lectins and ligands coming from the same tissue origin.

Human brain lectin: a soluble lectin that binds actin.

A biotinylated probe was used for detection of endogenous ligands of a human brain lectin on blotted human brain soluble proteins. Of the various proteins from brain extract resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, five reacted with the biotinylated probe. After elimination of saccharidic moieties by periodic treatment of the same extract, a single band with Mr approximately 43,000 was recognized by the lectin. This band was identified as actin using an anti-actin antibody. These results were confirmed by binding of biotinylated lectin to purified actin.

Electrophoretic study of conformational changes of a human soluble beta-D-galactoside-binding lectin upon storage.

Human brain lectin (HBL), a beta-galactoside specific soluble lectin, was purified by affinity chromatography. An alkylated derivative of this lectin was also prepared. Both native and modified molecules were conserved at -20 degrees C in the presence or absence of beta-mercaptoethanol, a reducing agent which was described to maintain the lectin activity in vitro or in the presence of beta-mercaptoethanol and lactose. The impact of storage conditions, over one year, on the native and derivated lectins, was analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, isoelectric focusing and titration curve, using the PhastSystem (Pharmacia). Western-blot analysis using an anti-HBL antibody and size-exclusion high performance liquid chromatography were used to complete the study. The subunit M(r)s were estimated before freezing (T0) and after three and twelve months (T3, T12). They were comparable for all preparations. In all samples tested, isoelectric focusing demonstrated the existence of at least three acidic proteins, with the pI ranging between 4.7-4.9. Titration curves clearly showed pH-dependent conformational changes, resulting in a panel of differently charged molecular species, some of which may be related to different oxidative states of the cysteine residues. We concluded that lectin can be stored at -20 degrees C for at least one year before use as a reagent since the modifications revealed by electrophoretic analysis do not alter the hemagglutination activity and carbohydrate binding properties. The immunoreactivity also remained unchanged.

Oligodendrocyte precursor migration and differentiation: combined effects of PSA residues, growth factors, and substrates.

Using the oligosphere strategy (V. Avellana-Adalid et al., 1996, J. Neurosci. Res. 45, 558-570), we compared the migratory behavior of oligodendrocyte preprogenitors (OPP) that expressed the polysialylated form of the neural cell adhesion molecule (PSA-NCAM) and of GD3-positive oligodendrocyte progenitors (OP). To study the role of PSA in OPP migration, we used endoneuraminidase-N, which specifically cleaves PSA from NCAM. Kinetic data showed that (i) migration velocity decreased with time and was favored on polyornithine compared to Matrigel; (ii) cells emerging from spheres enriched in PSA-NCAM+ OPP migrated farther than those from spheres enriched in GD3+ OP, their migration being enhanced by the addition of growth factors; (iii) removal of PSA from NCAM moderately reduced OPP migration and induced their differentiation in GD3+ OP and GFAP+ astrocytes; (iv) blocking integrins reduced their migration, suggesting an alternative mechanism of migration. Altogether these data illustrate that motility and differentiation of OPP involve the combinatorial action of PSA-NCAM, molecules of the ECM and their receptors, and growth factors.

Expansion of rat oligodendrocyte progenitors into proliferative "oligospheres" that retain differentiation potential.

The limited availability of enriched populations of oligodendroglial progenitors has impeded the exploration of the complex spatio-temporal mechanisms which dictate the chemical "language" of their biology. We have developed a technique to prepare homotypic aggregates of oligodendrocyte progenitors called "oligospheres." These were obtained using various approaches (sieving, Percoll gradient separation and differential adhesion) to purify oligodendroglial progenitors from newborn rat brain. Culturing cells in a mixture of N1 defined medium and conditioned medium from the B104 neuronal cell line in the absence of adhesive substrate allowed to expand routinely and extensively for several months, the oligodendrocyte progenitor population. Under these conditions, the resulting population consisted of 98% GD3-positive/GFAP-negative cells. After dissociation and plating on polyornithine coated substrates, in the presence of low (2%) or high (20%) serum, oligosphere-derived oligodendrocyte progenitors were induced to differentiate into GalC-positive oligodendrocytes or GFAP-positive astrocytes, respectively. When transplanted into the newborn shiverer mouse brain, oligospheres were able to provide a focal reservoir of migrating and myelinating cells. Oligospheres are thus ideal tools for exploring the biological and molecular events of the oligodendrocyte lineage both in vitro and in vivo.

Schwann cell transplantation and myelin repair of the CNS.

Studies with experimental models of dysmyelination and demyelination have shown that rodent Schwann cells including a Schwann cell line, transplanted in the central nervous system compete with host oligodendrocytes to remyelinate denuded central axons of the spinal cord. The myelin produced by transplanted SC around these central nervous system axons is structurally normal and restores, secure nerve conduction. In the presence of a favorable substrate, transplanted Schwann cells migrate over considerable distances (several mm) and are recruited by a demyelinated lesion which they will partially repair Thus Schwann cells, which can also support axonal growth, may be instrumental in central nervous system repair. In addition, the possibility of obtaining large quantities of human and non-human primate Schwann cells, makes it possible to consider autologous Schwann cell transplantation as a potential therapy for demyelinating or traumatic diseases. The various differences which may exist between rodents and humans, however, require further investigation of this possibility in a non-human primate model of demyelination. These experiments should provide not only insights on the potential of autologous transplantation in primates but also a better understanding of the process of central remyelination.

Plastic phenotype of human oligodendroglial tumour cells in vitro.

Human oligodendroglioma cells cultured in serum-supplemented media lose their oligodendrocytic antigenic markers and acquire astrocytic markers. However, after reimplantation in rodent brain, these cells re-express oligodendrocytic markers. This switch in human oligodendroglioma cell phenotype could result from the interplay of different stimuli in vitro vs in vivo The in vitro differentiation into astrocytes might result from non-physiological culture conditions. It is shown that human oligodendroglioma cells behave in a way similar to that of rodent bipotential 0-2 A progenitor cells which can be driven to differentiate into either oligodendrocytes or type 2-astrocytes depending on the culture medium. Indeed, in serum-supplemented medium, human oligodendroglioma cells proliferated and expressed the GFAP astrocytic marker. In chemically defined medium containing insulin, human oligodendroglioma cells were quiescent and expressed the OI oligodendrocyte-specific marker. In both media, human oligodendroglioma cells expressed the A2B5 membrane marker as well as the SCIP transcription factor specific of 0-2 A cells, further confirming their oligodendrocytic origin. Replacement of insulin by platelet-derived growth factor (PDGF) and basic fibroblast growth factor (bFGF), known to maintain 0-2 A progenitors in a proliferative state, stimulated DNA replication of human oligodendroglioma cells cultured in chemically defined medium.

Migration and multipotentiality of PSA-NCAM+ neural precursors transplanted in the developing brain.

By optimizing the previously described strategy for obtention of spheres enriched in PSA-NCAM+ precursors, we prepared PSA-NCAM-immunoselected cell populations from cerebral hemispheres of neonatal MBP-LacZ transgenic mice. These cells expressed Nestin, exhibited clonal expansion potential and formed spheres, which were initially enriched in PSA-NCAM+ cells but became enriched in GD3+ oligodendrocyte progenitors after 1 week in B104 contionned medium. One month after their periventricular transplantation into the brain of wild-type and/or shiverer newborn mice, cells from PSA-NCAM+ spheres exhibited a higher rostral migration potential than cells from GD3+ spheres, and clearly contributed to myelination in the olfactory bulb. In shiverer hosts, both sphere populations generated oligodendrocytes with similar myelination potential. In addition PSA-NCAM+ sphere cells generated GFAP+ astrocytes and NeuN+ neurons, depending on their site of insertion. These results evidence the high plasticity of newborn PSA-NCAM+ neural precursors and suggest that they are promising tools for cell therapy of CNS diseases, including myelin disorders.

Mouse oligospheres: from pre-progenitors to functional oligodendrocytes.

To study the biology and repair capacities of mouse oligodendroglial cells, we established cultures of cells purified from neonatal wild-type and 9.6-kb MBP-LacZ transgenic newborn mice cerebral hemispheres as free-floating aggregates in the continuous presence of neuroblastoma conditioned medium (N1-B104). In vitro analysis indicated that the initial cell preparations were enriched in oligodendrocyte pre-progenitors that expressed PSA-NCAM and GAP-43 but not GD3, O4, NF68 or glial fibrillary acidic protein (GFAP) markers. These pre-progenitors required increased concentrations of insulin and progesterone to allow their survival in vitro. With time in culture, spheres composed of oligodendrocyte pre-progenitors became oligospheres enriched in oligodendrocyte progenitors expressing GAP-43 and GD3. As well as conserving bipotentiality in vitro, these spheres were able to form myelin in vivo after transplantation into the neonatal shiverer mouse brain. Thus, the oligosphere strategy is a powerful method for generating large populations of mouse oligodendrocyte pre-progenitors and progenitors. The ability to generate oligospheres from transgenic mice will be instrumental in the further dissection of the molecular and cellular mechanisms of myelination and remyelination of the central nervous system.

Purification and characterization of a galactoside-binding lectin from human brain.

A beta-galactoside-binding hemagglutinin was detected in soluble extracts of human brain. This soluble lectin was purified to homogeneity by affinity column chromatography on lactose coupled to divinylsulfone-activated agarose. The purified lectin had an isoelectric point of 3.9 and its subunit molecular mass estimated by polyacrylamide gel electrophoresis in sodium dodecyl sulfate was 14,500. Human brain lectin was not a glycoprotein and its amino acid composition was characterized by a high content of serine, glutamic acid, and glycine, and a low content of methionine and cysteine. The most potent saccharide inhibitors tested were thiodigalactoside, lactose, and p-nitrophenyl-beta-D-galactoside. An antibody was raised to the pure lectin. Immunological relationships were found between the brain lectin and several other soluble lectins of various vertebrate origins.

Oligodendrocyte-type 2 astrocyte progenitors use a metalloendoprotease to spread and migrate on CNS myelin.

Oligodendrocyte-type 2 astrocyte (O-2A) progenitors are highly motile cells which migrate in the developing and adult central nervous system (CNS). Adult CNS myelin, however, contains inhibitory proteins, the neurite growth inhibitors NI 35/250, which block neurite outgrowth and spreading of many different cell types, such as astrocytes and fibroblasts. In the present study we investigated the spreading of dissociated cells and migration out of aggregates ('spheres') of primary O-2A cultures and of a glial precursor cell line (CG-4) on purified CNS myelin and on CNS tissue. Primary O-2A progenitors and CG-4 cells quickly attached to and spread on CNS myelin-coated culture dishes, showing no inhibition by the neurite growth inhibitors. CG-4 cells migrated with a velocity of 30 microns/h on a CNS myelin protein extract and at 5.7 microns/h on adult spinal cord tissue. Both cell spreading and migration on a CNS substrate could be specifically blocked by metalloprotease blockers like o-phenanthroline and the tetrapeptide carbobenzoxy-phe-ala-phe-tyr-amide, whereas blockers of the serine, aspartyl and cysteine proteases had no effect. On differentiation to astrocytes, the O-2A progenitors lost their ability to spread on CNS myelin. These results suggest the crucial involvement of a metalloprotease in the mechanism of migration on a CNS substrate. In vivo, migration of oligodendrocyte progenitors may be an important aspect of myelin repair following local traumatic, inflammatory or toxin-induced myelin loss.

Cell-cell interactions during the migration of myelin-forming cells transplanted in the demyelinated spinal cord.

In the present paper, Dil-labeled myelin-forming cells were traced after their transplantation at a distance from a lysolecithin induced lesion in the adult wild-type and shiverer mouse spinal cord. Optical and ultrastructural observations indicate that after their transplantation, Dil-labeled Schwann cells and oligodendrocyte progenitors were found at the level of the graft as well as at the level of the lesion thus confirming that myelin-forming cells were able to migrate in the adult lesioned CNS (Gout et al., Neurosci Lett 87:195-199, 1988). Between the graft and the lesion, labeled Schwann cells and oligodendrocyte progenitors were absent in the gray matter, but were found as previously described, in specific locations (Baron-Van Evercooren et al., J Neurosci Res 35:428-438, 1993; Vignais et al., J Dev Neurosci 11:603-612, 1993). Both cell types were found along blood vessel walls and more precisely in the Virchow-Robin perivascular spaces. They were identified in the meninges among meningeal cells, collagen fibers, or occasionally in direct contact with the basement membrane forming the glia limitans. In addition to these findings, three major observations were made. In the ependymal region, myelin-forming cells were localized between or at the basal pole of ependymocytes. While Dil-labeled oligodendrocyte progenitors were noted to migrate along the outer surface of myelin sheats in CNS wild-type and shiverer white matter, Schwann cells were excluded from this structure in the wild-type mouse spinal cord. Moreover, in the shiverer mouse, migrating Schwann cells did not seem to interact directly with myelin sheats nor with mature oligodendrocytes. Finally, both cell types were seen to invade extensively the spinal peripheral roots. Our ultrastructural observations clearly suggest that multiple cell-cell and cell-substrate interactions rule the migration of myelin-forming cells in the adult CNS infering that multiple mechanisms are involved in this process.

Expression of the highly polysialylated neural cell adhesion molecule during postnatal myelination and following chemically induced demyelination of the adult mouse spinal cord.

We have investigated the expression of the highly polysialylated neural cell adhesion molecule in the mouse spinal cord during postnatal myelination and in the adult after chemically induced demyelination. By double immunohistochemistry, using a monoclonal antibody (anti-Men B) which specifically recognizes polysialic acid (PSA) units on neural cell adhesion molecule (N-CAM), and an anti-myelin basic protein, a caudorostral gradient of expression of PSA-NCAM was observed at postnatal day 1 (P1), which was inversely related to the gradient of myelination. At P7, PSA-NCAM labelling decreased relative to P1. In white matter, this decrease was correlated with the progression of myelination. PSA-NCAM immunoreactivity persisted in as yet unmyelinated structures, i.e. the corticospinal tract, the dorsomedial part of the ventral funiculus and the lateral funiculi, and decreased with the onset of myelination of these structures at P15. In the adult, PSA-NCAM expression remained in discrete structures, i.e. laminae I and II of the dorsal horn and lamina X around the central canal. The ependymal cells and the astrocyte endfeet under the meninges were also labelled. In addition, PSA-NCAM expression was reinduced on various cells and structures after lysolecithin-induced demyelination of the adult mouse spinal cord. At early times after demyelination, PSA-NCAM was expressed on glial cells around the lesion but also at a distance from this zone. Seven days after injection, cellular PSA-NCAM expression was found around but also within the lesion. This expression was totally abolished 15 days after injection. Double immunohistochemistry for PSA and cell-specific markers showed that the cells which expressed PSA-NCAM after demyelination were oligodendrocyte precursors, reactive astrocytes and Schwann cells. PSA-NCAM re-expression on all cell types was transient and ceased when myelin repair was accomplished. The spatial and temporal regulation of PSA-NCAM expression during development and after demyelination suggests a role for PSA-NCAM in glial plasticity during the myelination and remyelination processes.

Inflammation promotes survival and migration of the CG4 oligodendrocyte progenitors transplanted in the spinal cord of both inflammatory and demyelinated EAE rats.

Oligodendrocyte progenitor CG4 cells were labeled with bisbenzimide and transplanted in the lumbar spinal cord of rats 15 to 17 days prior to the induction of experimental autoimmune encephalomyelitis (EAE). EAE was induced by immunization with the encephalitogenic peptide of myelin basic protein (amino acids 68-88; C1) in adjuvant, either alone or in combination with a single injection of an anti-myelin oligodendrocyte glycoprotein (MOG) antibody to enhance central nervous system (CNS) demyelination. In control animals without EAE, the survival and migration capacity of CG4 cells was minimal. In striking contrast, both the survival and migration of this oligodendrocyte progenitor cell line were greatly enhanced in animals with EAE. In both disease models, large number of CG4 cells were still found in the spinal cord 50 days after transplantation, by which time they had migrated up to 6 cm from the transplantation site. Migrating CG4 cells were found in the subpial space, around the ependyma and blood vessels, and as well as in the grey and white matter of the CNS parenchyma. In all these locations, the CG4 cells were often associated with reactive astrocytes. These data strongly support the concept that inflammatory responses within the CNS promote, rather than inhibit, the survival and migration of transplanted oligodendrocyte progenitors in the adult CNS.

In vitro and in vivo behaviour of NDF-expanded monkey Schwann cells.

Schwann cells, the myelin-forming cells of the peripheral nervous system may play a major role in the regeneration and remyelination not only of the peripheral but also of the central nervous system. The discovery of the mitogenicity of human recombinant forms of neuregulins (glial growth factors) on primate Schwann cells allows us to envisage a considerable expansion of these cells in culture with a view to autologous transplantation in the central nervous system. To assay this possibility, we used human recombinant neu-differentiation factor beta (NDFbeta) to expand monkey Schwann cells derived from perinatal and adult nerve biopsies. We report that NDFbeta containing the epidermal growth factor (EGF)-like domain (residues 177-228) is a potent mitogen for monkey Schwann cells but is more effective on perinatal than adult Schwann cells. Moreover, continuous treatment with NDFbeta, does not seem to prevent Schwann cells differentiation into myelin-forming cells after their transplantation into the demyelinated mouse spinal cord. These observations, in addition to the close similarities of in vitro behaviour which exist between human and monkey Schwann cells, indicate that monkey Schwann cells could be an ideal tool to study the potential and limits of autologous transplantation in a non-human primate model of central nervous system demyelination.

Changes in S-type lectin localization in neuroblastoma cells (N1E115) upon differentiation.

The distribution of a 14.4 kDa S-type lectin was examined in murine neuroblastoma cells, either undifferentiated or after differentiation induced by dibutyryl-cyclic adenosine monophosphate. In undifferentiated cells the immunoreactivity was detected extracellularly, associated with the plasma membrane and in bulges released into the extracellular milieu. Important modifications of the lectin localization were associated with the differentiation process that induced an increased cytosolic expression and a decreased externalization. Possible functions for the lectin expressed intracellularly in the differentiated cells are also considered.

Immunohistochemical localization of a beta-galactoside-binding lectin in rat central nervous system. II. Light- and electron-microscopical studies in developing cerebellum.

An endogenous brain lectin exhibiting beta-galactoside specificity (RBL-16) was localized during postnatal cerebellum development both at the light- and electron-microscopical level. The lectin was widely distributed in neurons, astroglial and perivascular cells. Its levels were nearly constant during development in the two latter cell types. The lectin was developmentally regulated with a transient accumulation in Purkinje dendritic spines between the 10th- and 13th day, then it decreased until adult age. From electron-microscopical observations, it could be concluded that, in Purkinje cells, the lectin remained in the intracellular compartment, in dendrites and cell bodies. It was never externalized in the region where synaptogenesis takes place. A role in the intracellular transport of molecules should be expected from such a localization. The lectin was also transiently found on the surface of postmitotic neuroblasts in the external germinative layer and on the parallel fibers of the upper part of the molecular layer. However, it was not expressed inside neuroblasts. This suggests that part of the lectin found on the surface of neuroblasts originates from heavily stained astrocytes which could secrete it. RBL-16 could be making bridges between neuroblasts in the premigratory zone and between growing axons. A role in transient neuroblast adhesion in the external germinative layer and in parallel fiber fasciculation is expected from such a localization.

Immunohistochemical localization of a beta-galactoside-binding lectin in rat central nervous system. I. Light- and electron-microscopical studies on developing cerebral cortex and corpus callosum.

From a lectin isolated from human brain (HBL-14), that specifically binds beta-galactosides, a polyclonal antiserum was raised that also recognizes a similar rat brain lectin (RBL-16). These antibodies allowed the immunocytochemical localization of the lectin during rat brain development by optical and electron microscopy. The presence of RBL-16, first detected at embryonic day 15, was specially increased from postnatal day 1 to 10. Its level decreased thereafter but it could still be detected in adult rat brain. The lectin, predominantly neuronal until postnatal day 13, was also present in astrocytes and perivascular cells where no developmental regulation was observed in contrast to neurons. Electron microscopy showed that the lectin was transiently expressed in the axoplasm of almost all neurons in layer I around the birth date, after which it remained inside neurons, including cell bodies and dendrites, in all examined regions. The lectin was clearly localized in postsynaptic structures. This beta-galactoside-specific lectin may be involved in synaptogenesis and neurite fasciculation as well as in intracellular traffic as discussed.