Establishment and characterization of a mouse Schwann cell line which produces myelin in vivo

Spontaneously immortalized adult mouse Schwann cells secrete autocrine and paracrine growth-promoting activities

We established spontaneously immortalized Schwann cell lines from long-term cultures of adult mouse dorsal root ganglia and peripheral nerves. One of the cell lines, designated IMS32, responded to mitogenic stimuli by platelet-derived growth factor (PDGF)-BB, acidic and basic fibroblast growth factors (aFGF, bFGF), and transforming growth factors (TGF)-beta 1 and -beta 2, as determined by bromodeoxyuridine (BrdU) incorporation and double immunofluorescence for S100 and BrdU. Furthermore, conditioned media (CM) obtained from IMS32 cells showed mitogenic activity for both IMS32 cells and long-term cultured Schwann cells. Western blot analysis revealed TGF-beta-like molecule in the CM, and the activity was absorbed with anti-TGF-beta neutralizing antibody. Reverse transcription followed by polymerase chain reaction (RT-PCR) of IMS32 RNA revealed that these cells expressed TGF-beta 1, -beta 2, and -beta 3 transcripts. When rat pheochromocytoma PC12 cells were incubated with the CM, they developed neurite growth. Coculture of PC12 and IMS32 cells also showed neurite growth of PC12 cells. RNA transcripts of nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF), neurotrophin-3 (NT3), ciliary neurotrophic factor (CNTF), and glial cell line-derived neurotrophic factor (GDNF) were detected from IMS32 cells by RT-PCR. In these, we sequenced the mouse GDNF cDNA coding region and observed 97% and 90% homologies to corresponding rat and human cDNA sequences, respectively. These results indicate that the immortalized Schwann cell line mitotically responds to various growth factors and secretes autocrine and paracrine growth-promoting activities in vitro.

Spontaneous equine pulmonary granular cell tumors: morphologic, histochemical, and immunohistochemical characterization

Spontaneous equine pulmonary granular cell tumors were diagnosed in six mature horses at slaughter. These tumors were grossly recognized as multiple (5/6) or single (1/6) creamy white, firm nodules. The tumors, located adjacent to bronchi and bronchioles, often invaded airways, resulting in partial to complete occlusion of the lumina. Neoplastic cells were rounded to polyhedral with numerous eosinophilic cytoplasmic granules that reacted uniformly positive with S-100 and neuron-specific enolase antibodies and multifocally with glial fibrillary acidic protein antibodies. These cells were negative for muscle-specific actin, lysozyme, cytokeratin, chromogranin A, and myelin basic protein antigens and did not stain with silver by the Grimelius technique. Uniformly blue-green and scattered pink intracytoplasmic granules were evident with luxol fast blue and periodic acid-Schiff counterstain for myelin and myelin breakdown products. Histochemical and immunohistochemical staining results of these tumors suggest that they are composed primarily of myelinating Schwann cells with lesser numbers of scattered nonmyelinating Schwann cells. The morphologic features of the equine pulmonary granular cell tumors are strikingly similar to those of endobronchial granular cell tumors of human beings.

Mitogenic effects of platelet-derived growth factor, fibroblast growth factor, transforming growth factor-beta, and heparin-binding serum factor for adult mouse Schwann cells

Mitogenic effects of fetal calf serum (FCS), platelet-derived growth factor (PDGF), fibroblast growth factor (FGF), transforming growth factor-beta (TGF-beta), and forskolin to adult mouse Schwann cells were examined by bromodeoxyuridine (BrdU) incorporation and double immunofluorescence for S100 and BrdU. PDGF-BB, basic FGF, and TGF-beta 1 and beta 2 were all mitogenic for Schwann cells in media containing FCS. Forskolin suppressed the mitogenic activity of these factors. In serum-free media, PDGF-BB and bFGF were also mitogenic, but TGF-beta 1 and beta 2 were not. Heparin-binding fractions of FCS obtained by heparin-Sepharose chromatography synergized with TGF-beta 1 and beta 2 to produce a mitogenic response. Since PDGF-BB, acidic FGF, and basic FGF were not detected in these fractions by immunoabsorption and immunoblot assays, the presence of unidentified heparin-binding molecules in FCS bioactive for adult mouse Schwann cells is suggested.

Transplantation of an oligodendrocyte cell line leading to extensive myelination

Oligodendrocytes, the myelin-forming cells of the central nervous system, can be generated from progenitor cell lines and assayed for their myelinating properties after transplantation. A growth-factor-dependent cell line of rat oligodendrocyte progenitors (CG4) was carried through 31-48 passages before being transplanted into normal newborn rat brain or the spinal cord of newborn myelin-deficient (md) rats. In md rat spinal cord, CG4 oligodendrocyte progenitors migrated up to 7 mm along the dorsal columns, where they divided and myelinated numerous axons 2 weeks after grafting. CG4 cells were transfected with the bacterial lacZ gene and selected for high beta-galactosidase expression. The cell migration and fate of these LacZ+ cells were analyzed after transplantation. In normal newborn brain, LacZ+ oligodendrocyte progenitors migrated along axonal tracts from the site of injection and integrated in the forming white matter. In md rats, extensive migration (up to 12 mm) was revealed by staining for beta-galactosidase activity of the intact spinal cord where many grafted cells had moved into the posterior columns. Similar migration and integration of grafted cells occurred in the spinal cord of normal myelinated rats and after a noninvasive grafting procedure. Thus, oligodendrocyte progenitors can maintain their ability to migrate and myelinate axons in vivo after multiple passages in vitro. Such progenitor cell lines can be used to study the molecular mechanisms underlying oligodendrocyte development and the repair of myelin in dysmyelinating diseases.

Diploid and hyperdiploid rat Schwann cell strains displaying negative autoregulation of growth in vitro and myelin sheath-formation in vivo

Neonatal rat Schwann cells were cultured for several months with intermittent exposure to the mitogen, cholera toxin, and infrequent passaging to avoid premature transformation. A cell line SCL4.1/F7 was derived following the cloning of one of these long-term cultures by limiting dilution in liquid medium to select for cells capable of continuous proliferation in the absence of mitogen. F7 cells have been passaged 40 times (80-120 generations) over 14 months. Two substrains were identified at passage 20, one of which ,s diploid and the other which has trisomy 7 (t7). The cell line displays a characteristic flattened or crescent-shaped morphology, substratum adhesion which is calcium-dependent in the millimolar range, and pronounced contact-inhibition of growth. Confluent or subconfluent cultures readily cease proliferation and change to a differentiated (stellate/bipolar) morphology through the mediation of an autocrine growth-inhibitory factor. F7 cells grafted into the site of a crush injury in adult rat sciatic nerves remained viable and myelinated host axons. F7 is the first clonally derived diploid immortal Schwann cell line to have been published and should provide a suitable tool for the study of the biochemical and cellular basis of sheath cell-neuron interactions, myelin stabilization in peripheral nerve and Schwann cell growth autoregulation.

In vitro and in vivo characterisation of glial cells immortalised with a temperature sensitive SV40 T antigen-containing retrovirus

An oncogene-carrying replication-defective retrovirus was used to establish immortalised lines of murine glial cells. Primary cultures of early postnatal cerebellar cells were infected with a retrovirus based on the Murine Moloney Leukemia Virus containing a temperature-sensitive mutant of the Simian Virus 40 large T antigen (SV40 T) oncogene and a gene coding for resistance to the antibiotic G418. Infected cells were selected in G418 and after several in vitro passages cells expressing the O4 antigen were established as a cell line. At a later time point O4-positive single-cell clones were established. Two different types of clones were obtained: 1) "plastic" clones consisting of cells which initially had a morphological and antigenic phenotype of young glial precursor cells but which gradually lost these features, and 2) "stable" cell clones including a clone with the immunological and electrophysiological characteristics of Schwann cells. Culture of the latter cells in the presence of 1 mM dibutyryl cyclic adenosine monophosphate for a period of at least 10 days induced a change in shape and a shift in antigen expression towards a more "differentiated" maturation stage. When the SV40 T O4-positive immortalised cell line isolated on the cell sorter was transplanted into demyelinated lesions in adult rats, cells were observed ensheathing axons and forming limited amounts of PNS-type myelin. Glial cells immortalised with a temperature-sensitive mutant of the SV40 T oncogene thus retain many physiological properties of their primary culture counterparts and can be induced to undergo limited differentiation in vitro and in vivo. These cell lines, which represent immature CNS glia or Schwann cells, are providing useful tools for investigating the role of cell surface antigens involved in neuron-glial interactions.

Future prospects in transplantation

In multiple sclerosis and experimental demyelination, oligodendrocytes and Schwann cells are able to repair myelin lesions of the central nervous system. Both cell types were successfully transplanted in demyelinated lesions of the adult rat and mouse spinal cord. However, from these studies performed in the absence of cell tracers, little could be concluded about the behavior of the transplanted cells in their host. The recent development of a variety of cell markers has provided the opportunity to investigate cell-cell and cell-substrate interactions during migration of the transplanted cells. Cell tracing should also help to identify the type of lesions and type of cells to be transplanted for myelin repair. In addition, a better understanding of the role of growth factors and their application to transplantation should lead to significant improvement in myelin repair of the lesioned central nervous system.

Pathways of migration of transplanted Schwann cells in the demyelinated mouse spinal cord

We have studied the behavior of Schwann cells transplanted at a distance from an induced myelin lesion of the adult mouse spinal cord. These transplanted cells were mouse Schwann cells arising from an immortalized cell line (MSC80) which expresses several Schwann cell phenotypes including the ability to produce myelin. The behavior of MSC80 cells was compared to that of purified rat Schwann cells transplanted in the same conditions. Schwann cells were labeled in vitro with the nuclear fluorochrome Hoechst 33342 and were transplanted at distances of 2-8 mm from a lysolecithin-induced myelin lesion in the spinal cord of shiverer and normal mice. Our results show that transplanted MSC80 cells migrated toward the lesion, in both shiverer and normal mouse spinal cord, preferentially along the ependyma, meninges, and blood vessels. They also migrated along white matter tracts but traveled a longer distance in shiverer (8 mm) than in normal (2-3 mm) white matter. Using these different pathways, MSC80 cells arrived within the lesion of shiverer and normal mouse spinal cord at the average speed of 166 microns/hr (8 mm/48 hr). Migration was most efficient along the ependyma and the meninges where it attained up to 250 microns/hr. Migration was much slower in white matter tracts (95 microns/hr +/- 54 in the shiverer and only 38 microns/hr +/- 3 in the normal mouse). We also provide evidence for the specific attraction of MSC80 cells by the lysolecithin-induced lesion since 1) their number increased progressively with time in the lesion, and 2) MSC80 cells left their preferential pathways of migration specifically at the level of the lesion. Finally, combining the Hoechst Schwann cell labeling method with the immunohistochemical detection of the peripheral myelin protein, P0, we show that some of the MSC80 cells which have reached the lesion participate in myelin repair in both shiverer and normal lesioned mouse spinal cord. A series of control experiments performed with rat Schwann cells indicate that the migrating behavior of transplanted MSC80 cells was identical to that of purified but non-immortalized rat Schwann cells.

Photoconverted carbocyanine DiI allows direct visualization of transplanted glial cells at the ultrastructural level

We have used the carbocyanine fluorochrome, DiI, to trace living glial cells (astrocytes, oligodendrocytes and immortalized Schwann cells) after their transplantation into the newborn shiverer and normal mouse brain. DiI fluorescence first detected on vibratome sections, was photoconverted into a stable, non-diffusible and electron-dense diaminobenzidine product. Both fluorescence and precipitate were found in the same cells and were detectable until 60 days after transplantation. At the ultrastructural level, DiI precipitate was contained within cytoplasmic vesicles scattered in the transplanted cell bodies and processes. Photoconversion did not interfere with the cell fine structure or predicted post-transplantation behavior. DiI is thus a suitable marker to trace, at the ultrastructural level, living cells after their transplantation.

Repair of a myelin lesion by Schwann cells transplanted in the adult mouse spinal cord

In multiple sclerosis and experimental demyelination, oligodendrocytes and Schwann cells are able to repair myelin lesions of the central nervous system. However, spontaneous myelin repair is often insufficient. Several approaches to enhance remyelination have been considered and transplantation of myelin-forming cells has been proposed as one of them. In this paper, we present results which confirm the ability of transplanted Schwann cells to remyelinate an induced demyelinated lesion of the spinal cord. Schwann cells were either purified Schwann cells isolated from 1-2-day-old rat sciatic nerves, or immortalized Schwann cells (MSC80) arising from a purified culture of 7-day-old mouse sciatic nerves. They were transplanted into or at a distance from a lysolecithin-induced lesion of the Shiverer spinal cord. Labelling of the Schwann cells with the fluorochrome Hoechst 33342 enabled us to trace them after transplantation in their host and evaluate their ability to reach and to repair the demyelinated lesion. Using the Hoechst-Shiverer model, we show that when transplanted in the lesion, cultured Schwann cells, even immortalized, are able to remyelinate such a lesion efficiently. In addition, when transplanted at a distance from the lesion, they are able to reach and repair the lesion in time frames which allow them to compete actively with host oligodendrocytes.