Segregation of Na(+)-channel gene expression during neuronal-glial branching of a rat PNS-derived stem cell line, RT4-AC.

RT4 is a family of cell lines isolated from an ethylnitrosourea-induced rat peripheral neurotumor. RT4-AC cells express both excitable membrane and glial cell properties. In a process called cell-type conversion, RT4-AC cells segregate these properties to generate three distinct derivative cell types which have been classified as either neuronal (RT4-E and RT4-B) or glial (RT4-D). In this report we demonstrate that: (1) upon cell-type conversion, Na(+)-channel mRNA expression segregates primarily with the RT4 neuronal derivatives, (2) the SkM2 Na(+)-channel gene, which was originally isolated from rat muscle cDNA libraries, is the predominant gene expressed by the RT4 neuronal derivatives, (3) the three rat brain Na(+)-channel genes I, II, and III and the muscle-derived SkM1 gene are not the principal Na(+)-channel genes involved in the segregation, although very low levels of message of these genes are detected, and (4) the RT4 glial derivative expresses slightly higher levels of message from rat brain genes I and II than the neuronal derivatives. Since the RT4 cell lines were derived from a peripheral neurotumor these results present the possibility that the SkM2 gene may be important in vivo in the rat peripheral nervous system.     

Clonal sublines of rat neurotumor RT4 and cell differentiation. V. Comparison of Na+ influx, Rb+ efflux, and action potential among stem-cell, neuronal, and glial cell types

A multipotential stem-cell-type cell line (RT4-AC) isolated from a rat peripheral neurotumor differentiates in culture into two neuronal-type cells (RT4-B and RT4-E) or into a glial-type cell (RT4-D). The neuronal classification of RT4-B and RT4-E cells is based on their positive response to veratridine in the tetrodotoxin-sensitive Na+-influx and Rb+-efflux assays and on the action potential observed upon hyperpolarized stimulation. In addition, these neuronal cell types do not synthesize two glial proteins, S100 protein (S100P) and glial fibrillary acidic protein (GFAP). The glial classification of RT4-D is based on the syntheses of S100P and GFAP. Additionally, RT4-D does not display veratridine-activated Na+ influx and Rb+ efflux nor action potential. The stem cell type, RT4-AC, expresses both neuronal and glial properties to a lesser degree. In the neuronal-type cell lines of the RT4 family (RT4-B and RT4-E), the large veratridine-activated Na+ influx can further be stimulated by scorpion toxin. The Na+ influx of the stem cell (RT4-AC), however, is only slightly stimulated by veratridine alone, but greatly stimulated by the addition of veratridine and scorpion toxin. These observations suggest that a progressive differentiation of voltage-dependent Na+ channels may have occurred by the cell-type conversion from the stem cell type to the neuronal cell types. The exact nature of the change in Na+ channels is currently not known.     

Clonal sublines of rat neurotumor RT4 and cell differentiation. VI. Chromosome analysis

The RT4 neurotumor cell system consists of clonally derived cell lines where a stem cell type segregates in vitro into three biochemically and morphologically different cell types, one glial and two neuronal types. This process has been termed cell-type conversion (M. Imada and N. Sueoka, 1978, Dev. Biol. 66, 97-108). Detailed cytogenetic analysis of the RT4 cell lines are described. Giemsa-banding analysis of 12 independent clonal isolates of the four different RT4 cell types showed a relatively stable karyotype. The stem cell line, RT4-AC, is diploid and most stable, and it has one 4q+ marker chromosome in place of a normal No. 4. This 4q+ marker was identified in all cell types of the RT4 system and was not observed in other cell lines of BDIX origin. The 4q+, therefore, is a chromosomal marker of the RT4 system. Consistent chromosome rearrangement was not found in any one of the cell-type conversions of the RT4-AC cells into the three derivative cell types. The relative stability of the karyotype of the different clonal isolates gives the RT4 system an advantage in studies of genetic regulation and expression of cell-type conversion in vitro. Also the 4q+ marker can be used to identify RT4 cells in coculture experiments or to distinguish RT4 cells in cases of suspected cell-line contamination.     

Clonal sublines of rat neurotumor RT4 and cell differentiation: IV. Cell surface proteins

There are stem cells in RT4 neurotumor that undergo spontaneous differentiation into three distinct cell types in culture (cell type conversion). Stem cells (RT4-AC) and one of the differentiated cell types (RT4-D) are tumorigenic and synthesize glial-specific S100 protein, while the others (RT4-B and RT4-E) are nontumorigenic and demonstrate some neuronal function. Interrelationships between cell surface proteins and differentiation of RT4 cells were analyzed. The surface proteins are radioiodinated by a lactoperoxidase method, separated by gel electrophoresis in two dimensions, visualized by autoradiography, and quantitated according to the relative radioactivity associated with each protein species. Integral surface proteins are compared in the present study which remain associated with plasma membrane after the extraction of radioiodinated cells with 0.1 N NaOH. The extraction also helps to remove serum proteins in the medium which are absorbed on cell surfaces and may be artifactually recognized as surface proteins. All RT4 cell types are complex in cell surface protein composition and nearly 100 integral surface proteins have been identified when all RT4 cell types are combined. Many unique proteins as well as common proteins have been identified. Considerable similarity exists between RT4-AC and RT4-D and between RT4-B and RT4-E. The two cell types of each pair are distinct yet share some common neurological and tumorigenic characteristics. In contrast, little similarity exists in other combinations of the two cell types, e.g., RT4-AC and RT4-E, etc. The results support the notion that the pattern of cell surface protein expression is a stable differentiation property and a characteristic set of proteins corresponds to each stage of differentiation.     

Structural characterization of Escherichia coli sialic acid synthase

Wnt-1, the vertebrate counterpart of the Drosophila wingless gene, plays an important role in the early morphogenesis of neural tissues. In this report, we have shown that overexpression of Wnt-1 can direct embryonic carcinoma P19 cells to differentiate into neuron-like cells in the absence of retinoic acid. Immunocytochemistry showed that these cells expressed neuronal markers, such as the neurofilament (NF) and microtubule-associated protein 2 (MAP2), but failed to express the glial cell marker, glial fibrillary acidic protein (GFAP). RT-PCR revealed that two basic helix-loop-helix (bHLH) genes, Mash-1 and Ngn-1, were up-regulated during the differentiation stage of Wnt-1-overexpressing P19 cells. These results suggest that the Wnt-1 gene promotes neuronal differentiation and inhibits gliogenesis during the neural differentiation of P19 cells, and that neural bHLH genes might be involved in this process.     

Developmental expression of glial markers in ependymocytes of the rat subcommissural organ: role of the environment

Summary The rat subcommissural organ (SCO), principally composed of modified ependymocytes (a type of glial cell), is a suitable model for the in vivo study of glial differentiation. An immunohistochemical study of the ontogenesis of rat SCO-ependymocytes from embryonic day 13 to postnatal day 10 shows that these cells express transitory glial fibrillary acidic protein (GFAP) from embryonic day 19 until postnatal day 3. However, S100 protein (S100) is never expressed in the SCO-cells, contrasting with the ventricle-lining cells of the third ventricle, which contain S100 as early as embryonic day 17. Environmental factors could be responsible for the repression of GFAP and S100 in adult rats, because GFAP and S100 are observed in ependymocytes of SCO 3 months after being grafted from newborn rat into the fourth ventricle of an adult rat. Neuronal factors might be involved in the control of the expression of S100, since after the destruction of serotonin innervation by neurotoxin at birth, S100 can be observed in some SCO-ependymocytes of adult rats. On the other hand, GFAP expression is apparently not affected by serotomin denervation, suggesting the existence of several factors involved in the differentiation of SCO-cells.     

Clonal sublines of rat neurotumor RT4 and cell differentiation: II. A conversion coupling of tumorigenicity and a glial property

RT4 is a neurotumor induced by ethylnitrosourea injection of a newborn BDIX rat. We demonstrated previously that heterogeneity in early cultures of RT4 tumor cells can be regularly reproduced in cultures of clonal stem cells (cell type conversion). Our previous studies included morphology, differentiation of neural properties, and chromosome number of “tumor-derived” and “stem cell-derived” differentiated cells. In this paper, these two sets of differentiated cells were examined further for three additional parameters, all of which are related to malignancy. The stem cell (AC) and one type of differentiated cell (D) cause tumors when subcutaneously injected into syngeneic animals, while the other two types (B and E) do not. The amounts of a 250,000 molecular weight cell surface protein, which is probably equivalent to LETS protein (large external transformation-sensitive protein) of hamster and mouse, and the levels of plasminogen activator were examined as possible markers of malignancy. As anticipated, nontumorigenic cells generally have a large amount of the 250,000 molecular weight cell surface protein and are low in plasminogen activator activities, whereas the reverse is true for tumorigenic cells. This supports the idea that B and E cells are nontumorigenic revertants. The cell type conversion phenomenon of RT4 neurotumor and the differentiation of mouse teratoma and myeloid leukemic cells share a number of similarities, but differ in that differentiated RT4 cells can propagate in vitro even after loss of tumorigenicity. The concomitant expression of tumorigenicity and the S100 protein production of the D cell, or of nontumorigenicity and B and E cell differentiation upon the conversion of the stem cell, may suggest a regulational coupling between the tumorigenicity and the expression of a glial protein (S100 protein) in D cells.     

NDRG2 as a marker protein for brain astrocytes

The protein NDRG2 (N-myc downregulated gene 2) is expressed in astrocytes. We show here that NDRG2 is located in the cytosol of protoplasmic and fibrous astrocytes throughout the mammalian brain, including Bergmann glia as observed in mouse, rat, tree shrew, marmoset and human. NDRG2 immunoreactivity is detectable in the astrocytic cell bodies and excrescencies including fine distal processes. Glutamatergic and GABAergic nerve terminals are associated with NDRG2 immunopositive astrocytic processes. Müller glia in the retina displays no NDRG2 immunoreactivity. NDRG2 positive astrocytes are more abundant and more evenly distributed in the brain than GFAP (glial fibrillary acidic protein) immunoreactive cells. Some regions with very little GFAP such as the caudate nucleus show pronounced NDRG2 immunoreactivity. In white matter areas, NDRG2 is less strong than GFAP labeling. Most NDRG2 positive somata are immunoreactive for S100ß but not all S100ß cells express NDRG2. NDRG2 positive astrocytes do not express nestin and NG2 (chondroitin sulfate proteoglycan 4). The localization of NDRG2 overlaps only partially with that of aquaporin 4, the membrane-bound water channel that is concentrated in the astrocytic endfeet. Reactive astrocytes at a cortical lesion display very little NDRG2, which indicates that expression of the protein is reduced in reactive astrocytes. In conclusion, our data show that NDRG2 is a specific marker for a large population of mature, non-reactive brain astrocytes. Visualization of NDRG2 immunoreactive structures may serve as a reliable tool for quantitative studies on numbers of astrocytes in distinct brain regions and for high-resolution microscopy studies on distal astrocytic processes.     

Glial cells in the central nervous system of earthworm, Eisenia fetida

Glial elements in the central nervous system of Eisenia fetida were studied at light- and electron microscopic level. Cells were characterized with the aid of toluidine blue, Glial Fibrillary Acidic Protein (GFAP), S100 staining. We identified neurilemmal-, subneurilemmal-, supporting-nutrifying- and myelinsheath forming glial cells. Both neuronal and non-neuronal elements are S100-immunoreactive in the CNS. Among glial cells neurilemmal and subneurilemmal cells are S100-immunopositive. With the antibody against the S100 protein one band is visible at 15 kDa. GFA P-immunopositive supporting-nutrifying glial cells are localized around neurons and they often appear as cells with many vacuoles. GFA P-positive cell bodies of elongated neurilemmal glial cells are also visible. Western blot analysis shows a single 57 kDa GFA P immunoreactive band in the Eisenia sample. At ultrastructural level contacts between neuronal and glial cells are recognizable. Glial cell bodies and their filopodia contain a granular and vesicular system. Close contacts between neuronal cell membranes and glial filopodia create a special environment for material transport. Vesicles budding off glial cell granules move towards the cell membranes, probably emptying their content with kiss and run exocytosis. The secreted compounds in return may help neuronal survival, provide nutrition, and filopodia may also support neuronal terminals.     

Immediate early gene IEX-1 induces astrocytic differentiation of U87-MG human glioma cells

The immediate early response gene IEX-1 is involved in the regulation of apoptosis and cell growth. In order to increase the apoptotic sensitivity to chemotherapeutic drugs and gamma-ray, we attempted to establish U87-MG human glioma cell line expressing IEX-1. Unexpectedly, however, transfection of IEX-1 into U87-MG glioma cells resulted in morphological changes to astrocytic phenotype and increase in glial differentiation marker proteins, S-100 and glial fibrillary acidic protein (GFAP). Glial cell differentiation was used to examine in rat C6 glioma cell line, since this cell line express astrocytic phenotypes by increase in intracellular cAMP concentration. Stimulation of human U87-MG glioma cells by membrane-permeable dibutyryl cAMP (dbcAMP) not only elicited their morphological changes but also induced expression of IEX-1 as well as S-100 and GFAP. H89, an inhibitor of protein kinase A (PKA), blocked dbcAMP-induced morphological changes of U87-MG cells and expression of IEX-1. In contrast, morphological changes and expression of S-100 and GFAP induced by IEX-1 were not affected by H89. Morphological changes induced by dbcAMP were totally abolished by functional disruption of IEX-1 expression by anti-sense RNA. These results indicate that IEX-1 plays an important role in astrocytic differentiation of human glioma cells and that IEX-1 functions at downstream of PKA.     

The expression of glial fibrillary acidic protein in a rat cerebellar cell line

A rat cerebellar cell line, WC5, derived by transformation with Rous sarcoma virus, which is temperature-sensitive for transformation (ts-RSV), can be induced to express glial fibrillary acidic protein (GFAP). Immunofluorescence, radioimmune assay, and electron microscopy studies show that GFAP is expressed in WC5 cells grown at the nonpermissive temperature (NPT), but not at the permissive temperature (PT) for transformation. GFAP is first detectable about 3 days after incubating cells at the NPT, and reaches an apparent plateau by the seventh or eighth day. The expression of GFAP is reversible; shifting cells from the NPT to the PT causes a dramatic decrease in GFAP after 96 hr. In order to determine if the expression of GFAP is linked to the temperature-sensitive transforming activity of the viral src gene product, phenotype revertants of WC5 were established. By the criteria of morphology and growth in agar, the revertant lines, in contrast to the parent cell line WC5, were shown to exhibit a transformed phenotype at both the NPT and PT. Immunofluorescence studies on several of the revertant cell lines show that they do not express GFAP at either the PT or NPT. These findings suggest that the expression of GFAP in WC5 is linked to the expression of the src gene product. The advantage of using ts-RSV to derive neural cell lines which exhibit differentiated properties is discussed.     

Neuroprotection by α-Lipoic Acid in Streptozotocin-Induced Diabetes

Glial cells provide structural and metabolic support for neurons, and these cells become reactive to any insult to the central nervous system. The streptozotocin (STZ) rat model was used to study glial reactivity and the prevention of gliosis by alpha-lipoic acid (alpha-LA) administration. The expression of glial fibrillary acidic protein (GFAP), S100B protein, and neuron specific enolase (NSE) was determined as well as lipid peroxidation (LPO) and glutathione (GSH) levels in some brain tissues. Western blot analyses showed GFAP, S100B, and NSE levels significantly increased under STZ-induced diabetes in brain, and LPO level increased as well. Administration of alpha-LA reduced the expression both of glial and neuronal markers. In addition, alpha-LA significantly prevented the increase in LPO levels found in diabetic rats. GSH levels were increased by the administration of alpha-LA. This study suggests that alpha-LA prevents neural injury by inhibiting oxidative stress and suppressing reactive gliosis.     

Neural Crest Cells Isolated from the Bone Marrow of Transgenic Mice Express JCV T-Antigen

JC virus (JCV), a common human polyomavirus, is the etiological agent of the demyelinating disease, progressive multifocal leukoencephalopathy (PML). In addition to its role in PML, studies have demonstrated the transforming ability of the JCV early protein, T-antigen, and its association with some human cancers. JCV infection occurs in childhood and latent virus is thought to be maintained within the bone marrow, which harbors cells of hematopoietic and non-hematopoietic lineages. Here we show that non-hematopoietic mesenchymal stem cells (MSCs) isolated from the bone marrow of JCV T-antigen transgenic mice give rise to JCV T-antigen positive cells when cultured under neural conditions. JCV T-antigen positive cells exhibited neural crest characteristics and demonstrated p75, SOX-10 and nestin positivity. When cultured in conditions typical for mesenchymal cells, a population of T-antigen negative cells, which did not express neural crest markers arose from the MSCs. JCV T-antigen positive cells could be cultured long-term while maintaining their neural crest characteristics. When these cells were induced to differentiate into neural crest derivatives, JCV T-antigen was downregulated in cells differentiating into bone and maintained in glial cells expressing GFAP and S100. We conclude that JCV T-antigen can be stably expressed within a fraction of bone marrow cells differentiating along the neural crest/glial lineage when cultured in vitro. These findings identify a cell population within the bone marrow permissible for JCV early gene expression suggesting the possibility that these cells could support persistent viral infection and thus provide clues toward understanding the role of the bone marrow in JCV latency and reactivation. Further, our data provides an excellent experimental model system for studying the cell-type specificity of JCV T-antigen expression, the role of bone marrow-derived stem cells in the pathogenesis of JCV-related diseases and the opportunities for the use of this model in development of therapeutic strategies.     

Time-lapse imaging reveals symmetric neurogenic cell division of GFAP-expressing progenitors for expansion of postnatal dentate granule neurons

Granule cells in the hippocampus, a region critical for memory and learning, are generated mainly during the early postnatal period but neurogenesis continues in adulthood. Postnatal neuronal production is carried out by primary progenitors that express glial fibrillary acidic protein (GFAP) and they are assumed to function as stem cells. A central question regarding postnatal dentate neurogenesis is how astrocyte-like progenitors produce neurons. To reveal cell division patterns and the process of neuronal differentiation of astrocyte-like neural progenitors, we performed time-lapse imaging in cultured hippocampal slices from early postnatal transgenic mice with mouse GFAP promoter-controlled enhanced green fluorescent protein (mGFAP-eGFP Tg mice) in combination with a retrovirus carrying a red fluorescent protein gene. Our results showed that the majority of GFAP-eGFP+ progenitor cells that express GFAP, Sox2 and nestin divided symmetrically to produce pairs of GFAP+ cells (45%) or pairs of neuron-committed cells (45%), whereas a minority divided asymmetrically to generate GFAP+ cells and neuron-committed cells (10%). The present results suggest that a substantial number of GFAP-expressing progenitors functions as transient amplifying progenitors, at least in an early postnatal dentate gyrus, although a small population appears to be stem cell-like progenitors. From the present data, we discuss possible cell division patterns of adult GFAP+ progenitors.     

A new protein (J1-31 antigen, 30 kD) is expressed by astrocytes,Müller glia and ependyma

Monoclonal antibody (MAb) J1-31 raised using human brain homogenate as immunogen in mice can be used as a cell type marker for certain types of CNS macroglia, namely astrocytes, Müller cells and tanycytes as well as ciliated ependymal cells. Except for the ciliated ependymal cells, these types of macroglia express glial fibrillary acidic protein (GFAP). J1-31 antigen is an intracellular protein which has a MW of 30 kD under reducing conditions for gel electrophoresis (Singhet al., 1986). This protein is distinct from GFAP (MW 50 kD) and vimentin (MW 55 kD), the two core proteins of 10 nm IFs known to be expressed in the above types ofmacroglia. This conclusion is based on several criteria including temporal differences in the onset of expression of GFAP and J1-31 antigen during development of the rat cerebellum. Also, there is no detectable (by immunofluorescence microscopy) expression of J1-31 antigen in the prenatal CNS or outside the CNS where vimentin has been reported to be abundant. The most direct evidence that J 1-31 antigen and GFAP are distinct proteins comes from studies on the mature ciliated ependymal cells which do not express GFAP and yet show intense immunostaining for J1-31 antigen.     

Detection of brain-specific gene expression in brain cells in primary culture: a novel promoter assay based on the use of a retrovirus vector.

Promoter activities of the brain-specific genes for glial fibrillary acidic protein (GFAP) and myelin basic protein (MBP) were investigated in brain cells in primary culture with the use of a novel retrovirus vector, pIP200. With this vector, promoter activity can be expressed in terms of beta-galactosidase activity. Differentiation of the primary brain cells to mature glial cells was not affected by treatment with the pIP200 virus vector. The 256-bp 5'-flanking region of the GFAP gene directed astrocyte-specific expression of lacZ. It was silent in fibroblasts, even in multiple copies. The 1.3-kb 5'-flanking region of the MBP gene exhibited strict tissue (oligodendrocyte) specificity under the present assay method but showed some leakiness when integrated into the chromosome in multiple copies. Promoter regions conferring cell type specificity in brain were effectively identified by the present method.     

Decreased gap-junctional communication associated with segregation of the neuronal phenotype in the RT4 cell-line family

RT4 is a family of cell lines derived from a rat peripheral neurotumor. The RT4 family consists of a multipotential stem-cell line that spontaneously gives rise to three derivative cell types, one glial and two neuronal. The three derivative cell types are capable of further lineage-specific maturation under appropriate culture conditions. Gap-junctional communication is postulated to be important during nervous-system development by allowing and/or controlling the transmission of both electrical current and signaling molecules, which may affect growth and differentiation. Our characterization of gap-junctional communication in the RT4 cell line family revealed that: (1) the glial-derivative and the stem-cell line were extensively coupled, while the two neuronal derivatives were significantly less coupled, and (2) all of the RT4 cell lines, including the stem-cell line, expressed Cx43 mRNA and protein, and the levels were generally consistent with the observed degree of functional coupling. These observations are consistent with data from in vivo studies and establish the RT4 cell line family as a potentially useful in vitro model system for understanding the role(s) of gap-junctional communication during differentiation in the peripheral nervous system.