Cellular and subcellular localization of LETS protein in the nervous system

Role of fibronectin-stimulated tumor cell migration in glioma invasion in vivo: clinical significance of fibronectin and fibronectin receptor expressed in human glioma tissues

In order to clarify the role of fibronectin in glioma invasion in vivo, we analyzed the relationship between fibronectin-stimulated cell migration and adhesion in 14 primary glioma cells and the expression of fibronectin and the fibronectin receptor in the corresponding tumor tissues. The tumors comprised nine glioblastomas (GB) and five anaplastic gliomas (AG) consisting of two astrocytomas, two oligoastrocytomas and one ependymoma. All glioma cells tested in the primary cell culture were found to migrate to fibronectin in a dose-dependent manner. The extent of cell migration to fibronectin was not significantly different for the GB and AG groups. On the other hand, cell adhesion to fibronectin in the AG was much stronger than that in the GB group. Immunohistochemistry demonstrated that fibronectin positively stained in the extracellular matrix (ECM) in eight cases and that the fibronectin receptor was positive in tumor cell membranes in 10 cases. In addition, cellular fibronectin isoforms containing ED-A and ED-B sequences were found to be immunolocalized in the tumor cells and the ECM of GB. These isoforms were also specifically expressed in tumor vessels within tumor tissues, but not in those within normal brain tissues. Cell migration tended to be expressed more strongly by glioma cells derived from tumor tissues in which fibronectin was positively immunolocalized in the ECM than from tissues with negative fibronectin in the ECM. Four glioma cells derived from GB whose tumor cells did not positively stain for fibronectin receptors migrated much less extensively to fibronectin than other glioma cells whose tissues showed positive staining for the fibronectin receptor. Of these four GB, two had loss of heterozygosity in the locus of fibronectin receptor beta1 gene. These results suggest that fibronectin deposited in the extracellular matrix of tumors, which can be derived from both plasma and the tumor cell itself, strongly promotes the migration of glioma cells, and that expression of the fibronectin receptor may play a critical role in the biological behavior of the tumor cells, particularly in fibronectin-stimulated cell migration in vivo.

Role of extracellular matrix in tumor invasion: migration of glioma cells along fibronectin-positive mesenchymal cell processes

OBJECTIVE

The major morbidity of glioma lies in its infiltrative growth. One of the major patterns of this invasive growth is the formation of Scherer's secondary structures associated with the blood vessels and the leptomeninges. To better understand the role of extracellular matrix (ECM) in glioma invasion, we investigated in vitro the interaction between glioma cells and the meningeal mesenchymal tissue from the brain. As an aid to this study, ECM in glioma cell line spheroids was compared with that in primary fetal brain aggregates.

METHODS

To study the expression of ECM, four glioma cell lines (U-87 MG, U-251 MG, AN1/lac-z, and HF-66) and primary cells from fetal rat brain were grown as spheroids and monolayers. To sudy the role of ECM in glioma invasion, spheroids from the glioma cell lines were grown over established cultures of fetal meningeal and mesenchymal tissue. Expression of fibronectin, laminin, tenascin, collagen VI, and chondroitin sulfate proteoglycan was studied by immunofluorescence.

RESULTS

Expression of ECM by the spheroids was variable. U-87 MG expressed most of the ECM components robustly, whereas AN1/lac-z expressed them all weakly. Fetal rat brain aggregates produced minimal ECM. In cocultures of glioma spheroids and fetal meningeal mesenchymal tissue, individual cells from the glioma spheroids that expressed least fibronectin (AN1/lac-z and U-251 MG) migrated along the fibronectin-positive mesenchymal cells in the culture dish. Cells from the other two lines (U-87 MG and HF-66) that expressed fibronectin strongly did not demonstrate such behavior. None of the other ECM components showed a similar association; mesenchymal cells did not express laminin as strongly as fibronectin, and glioma cells were not observed to align with the laminin-positive structures.

CONCLUSION

This study suggests that fibronectin may play a key role in intracerebral invasion of glioma cells.

Role of extracellular matrix proteins in regulation of human glioma cell invasion in vitro

Primary brain tumors lack the metastatic behavior that is in part believed to be promoted by the extracellular matrix (ECM) components of the basement membrane. This study was intended to examine the influence of the ECM components present in the basement membrane that may act as natural barriers to tumor cell invasion. We examined the effect of type I and type IV collagens, fibronectin, laminin, and hyaluronic acid on the migration and invasion of four established glioblastoma cell lines, SNB19, U251, UWR1, and UWR2. Lower concentrations of all the ECM components induced the migration and invasion of all the cell lines. However, in the case of SNB19, laminin inhibited both migration and invasion in a concentration-dependent manner. We have also examined the influence of individual ECM components on the migration of cells from a spheroid to a monolayer on ECM component-coated coverslips. Consistent with the invasion studies using the modified Boyden chamber assays, lower concentrations of ECM components induced the migration of cells from spheroids to monolayer. Again, laminin inhibited the migration of cells from SNB19 spheroids. These results indicate that ECM components induce the invasion of glioma cells, apart from components like laminin, which may act as natural inhibitors.

Regional and ultrastructural distribution of the alpha 8 integrin subunit in developing and adult rat brain suggests a role in synaptic function

Integrins are heterodimeric cell adhesion molecules comprised of alpha and beta subunits that have been implicated in the regulation of neuronal migration, differentiation, and process outgrowth. They mediate both cell-extracellular matrix and cell-cell interactions. The integrin alpha 8 beta 1 is a receptor for fibronectin, tenascin, and vitronectin that has been localized to axonal tracts and several types of non-neuronal cells in chick embryos and to smooth muscle cells in adult mammalian tissues. In this report, we describe the distribution of the alpha 8 subunit in the developing and adult mammalian brain. By light microscopy, alpha 8 labeling in the rat brain was found predominantly in neurons. It was primarily localized within perikarya and dendrites, but was also observed in certain fiber tracts. alpha 8 immunoreactivity was most concentrated in the olfactory bulb, hippocampal formation, substantia nigra, ventral tegmental area, and superior olivary complex, but was also found at moderate levels in several regions including layer 5 of the cerebral cortex. alpha 8 labeling was detected as early as E16, peaked in most areas during the first 3 postnatal weeks, and persisted in the adult. Electron microscopic analysis of the adult hippocampal formation revealed a striking concentration of alpha 8 immunoreactivity in the spines and postsynaptic densities of dendrites. These results suggest that alpha 8 is involved in the regulation of axonal and dendritic growth of some neurons in the developing central nervous system (CNS) and provide ultrastructural evidence that integrins may participate in the formation, maintenance, or plasticity of synapses.

Studies on the cell tropism of Listeria monocytogenes in ovine fetal brain cell cultures

The uptake of Listeria monocytogenes by cells in primary dissociated brain cell cultures prepared from ovine fetuses at approximately 50 to 60 days of gestation was studied using a sequential double immunofluorescence technique with antibodies against cell type-specific markers and the bacterial pathogen. Cell cultures were inoculated with bacteria at day 4, 8, and 15 in vitro. Listeria monocytogenes was predominately internalized by CD68-positive macrophages, followed by astrocytes, fibronectin-expressing cells, and neurons. An uptake of the bacterium by galactocerebroside (GC)-positive oligodendrocytes, which were first detected at day 15 in vitro, did not occur. Although a tropism for neurons was not observed, the susceptibility of neurons for infection with Listeria monocytogenes is in accordance with the supposed intraaxonal migration of the bacterium in the pathogenesis of focal brain stem encephalitis. The pattern of the infection rates of ovine brain cell types was similar to that shown in murine fetal brain cell cultures, indicating that there is no species-specific brain cell tropism of the bacterium.

Immunohistochemical localization of extracellular matrix proteins in human glioma, both in vivo and in vitro

Expression of type IV collagen, fibronectin and laminin in various types of primary human brain tumor sections and normal brain tissue sections as well as cultured glioma cell lines was examined by an immunofluorescence technique. Type IV collagen, fibronectin, and laminin were mainly localized to the basement membrane of the vasculature in glioblastoma, anaplastic astrocytoma, low grade glioma, and in normal brain. However, positive staining for all the extracellular matrix (ECM) components tested was found only in glioblastoma sections both in the cells and in the ECM. In all other tumor types and in normal brain tissue, the cells did not stain for any of the ECM components. Four glioblastoma cell lines and autologous ECM synthesized by respective glioblastoma cell lines also showed positive staining for type IV collagen, fibronectin and laminin in vitro. These results suggest that glioblastoma cells both in vitro and in vivo express the extracellular matrix components that are involved in the regulation of tumor cell invasion.

On the existence of a cartilage-like proteoglycan and link proteins in the central nervous system

Monoclonal antibodies (mAbs) against the major constituents of cartilage extracellular matrix, aggrecan and link protein, were screened by indirect immunofluorescence on frozen sections of bovine spinal cord. Antibodies against aggrecan and link protein gave rise to very similar perineuronal labeling in spinal cord gray matter. Aggrecan and link protein reactivities were seen in other regions of the central nervous system (CNS), although their distributions were not always coincident. Pretreatment of the tissue section with Streptomyces hyaluronidase, which is hyaluronate-specific, led to the loss of both reactivities. On Western blots, anti-aggrecan mAbs reacted with a large chondroitin sulfate proteoglycan. The chondroitinase-treated CNS proteoglycan co-migrated with the chondroitinase- and keratanase-treated cartilage proteoglycan. In CNS tissue homogenates, the addition of Streptomyces hyaluronidase brought about the release of the proteoglycan from the tissue. Anti-link protein mAbs were reactive with two species in the bovine CNS, the mobilities of which were very similar to those of the cartilage link proteins. The release of these species from the tissue required hyaluronidase. A rabbit antiserum against aggrecan was used to identify a similar proteoglycan in the rat CNS. In spinal cord-derived cell cultures, the labeled material was associated with astrocytes. An aggrecan cDNA hybridized to a 9.5 kb mRNA in the rat CNS. We conclude that the perineuronal matrix consists, in part, of a hyaluronate-bound aggrecan-like proteoglycan and link proteins, and that the former is produced by astrocytes.

Infection of murine fetal brain cell cultures with Listeria monocytogenes

The uptake of Listeria monocytogenes by different brain cells was studied in primary dissociated brain cell cultures derived from murine fetuses. In respect to the supposed intraaxonal migration of Listeria monocytogenes in the pathogenesis of listeric focal brain stem encephalitis, it was examined whether the bacterium was internalized by neurons. Infection rates of distinct cell types were determined by double immunofluorescence with antibodies against cell type-specific markers and the bacterial pathogen. Because of the changing composition of the cultures and time-dependent expression of the oligodendrocyte marker galactocerebroside (GC), infections were carried out on day 4, 6, 8, and 15 in vitro. Listeria monocytogenes was detected predominantly within macrophages. Astrocytes, oligodendrocytes, and fibronectin-expressing cells were infected to a lesser extent. The lowest rates of infection were observed in neurons. A tropism of Listeria monocytogenes for neurons was not detected in vitro.

Extracellular matrix modulates the proliferation of rat astrocytes in serum-free culture

The mechanism of glial proliferation in the developing nervous system, as well as in response to injury, inflammation, and tumor invasion, is unknown. Several growth factors and extracellular matrices have been shown to stimulate the proliferation of cultured cells of various origin, including astrocytes. We investigated the effect of extracellular matrix components, including fibronectin (FN), laminin (LN), and collagen types I and IV, on the growth of astrocytes during stimulation by various growth factors. When astrocytes were grown on FN- and LN-coated wells in a serum-free, chemically defined medium, their increase in number significantly exceeded that of cells grown on plastic wells. The addition of platelet-derived or basic fibroblast growth factor to cells cultured on FN- or LN-coated wells significantly potentiated astrocyte proliferation. The collagen preparations had no such effect. These observations indicate that FN and LN have a fundamental part in converting the quiescent astrocyte into the proliferating phenotype, which may be required for remodelling damaged brain tissues in vivo.

Tumoral invasion in the central nervous system

During growth, migration and differentiation, cells closely interact with the extracellular matrix (ECM). The harmony between cells and their environment is a key factor that maintains the normal architecture of tissues. Loss of growth control is not the only characteristic of oncogenesis, loss of control by the ECM is an important event that allows malignant cells to further progress toward invasion and metastasis. Changes in cell adhesion, proteolytic degradation of the ECM and cell migration have all been described during invasion of most tissues by tumor cells. However little is known of these changes in tumors of the central nervous system (CNS). Although brain tumor cells may share some of the invasive characteristics of tumors that arise outside the CNS, the particular structure and composition of the brain ECM suggest the existence of unique invasive mechanisms in these tumors. Furthermore, the interaction between brain tumor cells and their ECM may explain the intriguing observation that despite their highly invasive behavior, these cells remain poorly metastatic. This review focuses on biochemical mechanisms essential for tumor invasion and how they relate to invasion of tumors that arise in the CNS.

Effects of transforming growth factor-beta 1 on the extracellular matrix and cytoskeleton of cultured astrocytes

The present study was performed on primary cultures and subcultures of cerebellar astrocytes in order to investigate the effects of transforming growth factor-beta 1 (TGF beta 1) on proliferation, extracellular matrix (ECM) components, and cytoskeletal structures in relation to morphological changes. The expression and cellular distribution of the ECM components laminin and fibronectin and the cytoskeletal proteins glial fibrillary acidic protein (GFAP) and actin were investigated by immunoblotting, immunocytochemistry, and phalloidin staining. The proliferation of primary cultures was strongly inhibited by TGF beta 1. Treated cells became enlarged and spread onto the substratum. TGF beta 1 promoted the appearance of actin stress fibers and increased the cell actin content. It elicited a slight increase in GFAP expression and induced dispersion of thin filaments of GFAP. TGF beta 1 also stimulated the production of laminin and fibronectin and their incorporation into the ECM of primary cultures grown in medium with or without serum. Astrocytes grown in serum-containing medium for 1 day after subculturing responded strongly to TGF beta 1. Changes promoted by TGF beta 1 in cell shape, cytoskeleton, and ECM production of cultured astrocytes may have relevance for understanding the mechanisms of action of TGF beta 1 during brain development.

Infection of ovine fetal brain cell cultures with cytopathogenic and non-cytopathogenic bovine viral diarrhoea virus

The in vitro cell tropism of non-cytopathogenic (ncp) and cytopathogenic (cp) bovine viral diarrhoea virus (BVDV) was studied in primary dissociated brain cell cultures derived from ovine fetuses of different gestational ages. The cell types infected were identified by double immunofluorescence using antibodies against BVDV and cell type-specific markers. In cultures infected with ncp BVDV viral antigen was present in neurofilament (NF 200 kDa)-positive neurons, glial fibrillary acidic protein (GFAP)-positive astrocytes and fibronectin-expressing cells. Estimation of the percentages of individual cell types infected with ncp BVDV indicated a tropism for NF 200-positive neurons. In cultures infected with cp BVD virus cytopathic changes were observed beginning at 40 hours post infection. Viral antigen was present in vacuolated NF 200-, GFAP- and fibronectin-positive cells. In comparison with non-infected control cultures a considerable reduction of the number of the different cell types was seen.

Fluorescence labeling of the capillary network in rat brains

To assess the reliability of fluorescence methods for a quantitative staining of brain capillaries, three different immunohistochemical fluorescent markers were used in the rat brain. Staining of the basement membrane by antibodies directed against fibronectin was compared, in the same brain section, with simultaneous staining of the vascular endothelium constituents nonmuscle myosin or von Willebrand factor (factor VIII). These stainings all resulted in identical patterns, which demonstrates their suitability for capillary staining in the brain. It has been claimed that fixation of the tissue results in the appearance of spurious capillary spots. Such a fixation artifact could be excluded using nonmuscle myosin staining. These results validate the methods of quantitative fluorescent microscopical staining of capillary morphology in the brain and therefore support our concept of a continuous perfusion of all capillaries in the brains of conscious rats.

Reorganization of the ependyma during axolotl spinal cord regeneration: changes in intermediate filament and fibronectin expression

Changes in intermediate filament content and extracellular matrix material showed that the injury response of ependymal cells in lesioned axolotl spinal cord involves an epithelial-to-mesenchymal transformation, and that fibrous astrocytes are excluded from the remodeling lesion site. Antibody localization was used to visualize cytokeratin-, vimentin-, and glial fibrillary acidic protein- (GFAP-) containing intermediate filaments, as well as the adhesive glycoprotein fibronectin. In normal axolotl spinal cord cytokeratins were found near the apical surface of the ependymal cells. Transmission electron microscopic examination suggested that these cytokeratins were in tonofilaments. Cytokeratin expression was lost and vimentin production was initiated in ependymal cells 2-3 weeks following spinal cord injury. There was a period of approximately 1-2 weeks when cytokeratins and vimentin were co-expressed in vivo. This co-expression was maintained in vitro by culture on a fibronectin-coated substratum. As the central canal reformed, vimentin expression was lost. Ependymal cells lacked GFAP intermediate filaments, but GFAP was present in fibrous astrocytes of the neuropil and white matter. Following injury, GFAP localization showed that fibrous astrocytes disappeared from the remodeling lesion site and reappeared only after the ependymal epithelium reformed and newly myelinated axons were found. Fibronectin expression closely followed the expression of vimentin during mesenchymal ependymal cell outgrowth. These results suggest that the ependymal cell outgrowth requires changes in cell shape followed by changes in production of extracellular matrix.

Immunohistochemical evidence for transient expression of fibronectin in the developing dorsal lateral geniculate nucleus of the ferret

In recent years, the important role of the extracellular matrix in neural development has been increasingly recognized. In order to begin to examine what role might be played by the extracellular matrix in the developing dorsal lateral geniculate nucleus (dLGN), the present study used immunocytochemistry to assess the distribution of a recognized extracellular matrix molecule, fibronectin (FN), during postnatal development of the ferret dLGN. Prior to the segregation of cell layers, no clear pattern of FN distribution can be distinguished within the dLGN. By P16, when layers A and A1 are separated by an interlaminar space, FN is localized in that space. By P24, FN is present not only between layers A and A1, but also within layers A and A1 as bands parallel to the laminar borders. These bands appear to correspond spatially and temporally to the development of sublaminar boundaries in the ferret (Hahm and Sur, Neurosci Abstr 14:460, 1988). By the end of the first postnatal month, immunoreactivity is diminished but still present. FN is no longer present at P44 or in the adult. Adjacent sections were incubated with antiserum to glial fibrillary acid protein (GFAP). When a laminar pattern of GFAP can be distinguished, it coincides with the interlaminar distribution of FN. The findings described here are consistent with a role for FN in the development of a laminar organization in the dLGN.

Fibronectin immunoreactivity in neural trauma

The presence of extracellular matrix protein fibronectin (FN) at the site of neural trauma was examined using immunohistochemical methods. At 2, 4 and 7 days following a penetrating wound through the rat cerebral cortex, FN staining was detected in the neuropil and in non-neuronal cells adjacent to the wound. FN-stained cells were GFAP-negative and were identified as brain macrophages based on cell surface staining for CR3 complement receptor. Our findings suggest a role for FN in the repair of neural trauma.

Primary culture and cryopreservation of mouse astrocytes under serumfree conditions

The methods of primary culture and cryopreservation of mouse astrocytes under serum-free conditions were examined. Cerebra from newborn C3H/He mice were employed as the source of astrocytes. The cultured cells were able to grow in a serum-free, chemically defined medium containing transferrin, hydrocortisone, biotin, sodium selenite, insulin, fibroblast growth factor and epidermal growth factor. After the culture was maintained in the medium for 3 weeks, purity was assessed using immunofluorescence staining. The great majority of the cells (greater than 98%) contained glial fibrillary acidic protein and S-100 protein which are cell markers of astrocytes. To cryopreserve the enriched astrocytes under serum-free conditions, various cryoprotectants were examined. The combination of 10% dimethylsulfoxide and 0.1% methylcellulose gave the highest survival rate. These methods of primary culture and cryopreservation will be useful in physiological and biochemical studies which require mouse astrocytes.

Virulent and attenuated canine distemper virus infects multiple dog brain cell types in vitro

Canine Distemper Virus (CDV) produces an encephalitis in dogs that varies with viral strain. We have studied the cell tropisms of two virulent strains (CDV-SH and CDV A75-17) and an attenuated strain, Rockborn (CDV-RO), in cultured canine brain cells. Infected cell types were identified by double immunofluorescent labeling of specific cell markers and viral antigens. All viral strains studied produced infection in astrocytes, fibroblasts, and macrophages. Neurons were not infected by CDV A75-17 but were rapidly infected by CDV-SH and CDV-RO. Multipolar oligodendrocytes were very rarely infected by any of the virus strains. In contrast, a morphologically distinct subset of bipolar oligodendrocytes were commonly infected by CDV-SH and CDV-RO. The kinetics of infection in the astrocytes, oligodendrocytes, neurons, and macrophages varied between strains. Both CDV-SH and CDV-RO rapidly infected bipolar oligodendrocytes, astrocytes, neurons, and macrophages by 14 days post infection while infection by CDV A75-17 was delayed until after 28-35 days post infection. The differences in the growth kinetics and cell tropisms for some brain cells, exhibited by the three viral strains examined in this in vitro study, may relate to the different CNS symptoms that these strains produce in vivo.

Isolation of cDNAs from a mouse astroglial cell line by a subtracted cDNA library

Astrocytes belong to the glial cell population and represent a major subclass of the CNS. Although different subtypes of astrocytes have been described according to their morphological characteristics, biochemical markers of each subtype of astrocytes are not yet available. We have thus undertaken to compare gene expression pattern of different astroglial subtypes. In this study we have taken advantage of two astroglial cell clones derived from 8 day postnatal mouse cerebellar explants and which might be the in vitro equivalents of the velate protoplasmic (D19) and of the Golgi-Bergmann (C8S) astrocytes (Alliot and Pessac, Brain Res., 306: 283-291, 1984). We have constructed a subtracted cDNA library derived from cytoplasmic poly(A)+ RNAs of the D19 cell line. This library was enriched 12-fold for D19 specific sequences by subtractive hybridization with an excess of cytoplasmic poly(A)+ RNAs purified from the C8S astroglial clone. This subtracted library was differentially screened with cDNA probes derived from D19 and C8S cell lines; both probes were subtracted with C8S poly(A)+ RNAs. Eight cDNA clones corresponding to transcripts overexpressed in D19 were selected. Three cDNAs encode for smooth muscle actin, one for fibronectin and one for polyadenylate binding protein. The three other gene products have not been previously reported. The in vivo distribution pattern of these sequences in various mouse adult tissues shows that all these transcripts are expressed in the cerebellum and/or in the brain.

Immunocytochemical studies of cardiac myocytes and other non-neuronal cells of the fetal human heart in culture

Non-neuronal cell types present in cultures dissociated from the atria and ventricles of human fetal hearts, from 9 to 21 weeks' gestation, were studied using phase-contrast optics and immunocytochemistry. All atrial myocytes and many, if not all, ventricular myocytes observed in culture contained atrial natriuretic peptide-like immunoreactivity. Generally, the atrial natriuretic peptide-like immunoreaction in atrial myocytes was more intense and widespread than in ventricular myocytes. Atrial and ventricular fibroblasts expressed extracellular fibronectin-like immunoreactivity. A population of cells with the appearance and growth properties of endothelial cells was observed in both atrial and ventricular cultures, and was classified as endothelioid since their precise origin was not known. Only a subpopulation of these endothelioid cells contained factor VIII-related antigen immunoreactivity, and some cells that did not display the other growth characteristics of endothelial cells were also factor VIII-related antigen immunoreactive in culture. Glial cells were S-100-like immunoreactive; they were usually more numerous in atrial than ventricular preparations. There was no close association between glial cells and neurones in the atrial cultures.

Expression of sensory neuron antigens by a dorsal root ganglion cell line, F-11

The F-11 cell line is a fusion product of embryonic rat dorsal root ganglion (DRG) cells with mouse neuroblastoma cell line N18TG-2 (Platika, D., Boulos, M.H., Baizer, L. and Fishman, M.C., Proc. Natl. Acad. Sci. U.S.A., 82 (1985) 3499-3503). F-11 cells were uniformly labelled using a monoclonal antibody (RT-97) to the 200 kDa subunit of neurofilament protein, which labels a subpopulation of adult rat DRG neurons. F-11 cells did not stain for antigenic markers of fibroblasts or Schwann/satellite cells which are also present in DRG. Monoclonal antibodies that recognize cell surface carbohydrates have been shown to label subpopulations of DRG neurons. The stage-specific embryonic antigens SSEA-3 and SSEA-4, and the antigen recognized by B23D8, were expressed by some F-11 cells but not by the neuroblastoma parent of the hybrid cells. SSEA-3 was expressed by about 20% of the F-11 cells, whereas 40-60% expressed SSEA-4 or the antigen recognized by B23D8. The stability of F-11 cell subpopulations for sensory antigen expression was demonstrated by isolating single cells and growing the progeny as clonal lines. In some subclones, nearly 100% of the cells stably expressed SSEA-4 and/or B23D8, or failed to stain with anti-SSEA-4, anti-SSEA-3, or B23D8 over 12 passages. Other subclones were unstable for the expression of these antigens. This study demonstrates the derivation of the F-11 cell line from sensory neurons but also indicates that multiple phenotypes of varying stability are present in this line. This information is important for the use of this line as a model for DRG neurons.

A neuroectoderm-associated ganglioside participates in fibronectin receptor-mediated adhesion of germinal cells to fibronectin

Previous studies with a rat neural cell line have shown that the D1.1 ganglioside, an O-acetylated derivative of GD3, is involved in cellular adhesion to fibronectin. In vivo, D1.1 is present on germinal cells of the developing rat central nervous system, but not on postmitotic cells that migrate away from the germinal zones. These observations suggest that D1.1 could participate in adhesive interactions with germinal zones and that the loss of D1.1 could be involved in the decision to being migration. In support of this hypothesis, immunofluorescence histochemistry shows that both fibronectin and fibronectin receptor are colocalized with D1.1 in the ventricular zones of the embryonic rat brain and in the external granule cell layer of the postnatal cerebellum. Dishes coated with monoclonal antibody against D1.1 were used to isolate D1.1-positive germinal cells from Embryonic Day 14 cerebrum and from Postnatal Day 6 cerebellum. These cells are able to adhere to fibronectin-coated dishes by a mechanism that is inhibitable by a synthetic hexapeptide containing the arg-gly-asp cell recognition sequence of fibronectin. Adhesion is also partially inhibited by antibody against fibronectin receptor and is slowed by anti-D1.1 antibody, implicating both the receptor and the ganglioside in the adhesion process. During 3 days in culture these D1.1-positive, fibronectin receptor-positive cells exhibit a neuronal phenotype, as judged by morphology and staining with tetanus toxin. This further confirms the neuroepithelial origin of the cells. The cells do not synthesize detectable amounts of fibronectin, thus leaving unidentified the source of the fibronectin seen in the germinal zones in tissue sections. Immunoprecipitation experiments show that the fibronectin receptors present on these cells are heterodimers. Under nonreducing conditions, the immunoprecipitates contain an alpha-subunit of 150-160 kDa and a beta-subunit of 115-125 kDa.

The development of an animal model of glioma for use in experimental neuro-oncology

A cell line, 497-P(1), derived from the VM spontaneous murine astrocytoma has been used to develop an in vitro in vivo model of human glioma. This paper describes the growth characteristics of tumours produced after intracerebral or subcutaneous inoculation of 497-P(1) cells into syngeneic VM mice. The results show that cell line 497-P(1) provides the basis for a reproducible animal model of glioma which fulfils many of the criteria required for experimental therapy studies.

Selective attachment of neural cells to specific substrates including Cell-Tak, a new cellular adhesive

Adherence of embryonic hypothalamic cells and a homogeneous neuronal cell line was assessed on various substrates and compared to attachment to the new cellular and tissue adhesive, Cell-Tak. Cell-Tak provided the most advantageous surface with 100% of fetal brain cells attaching in 5 h. Attachment of hypothalamic cells to compounds such as poly-D-lysine or collagen within this time was increased by 45 and 25%, respectively, over tissue-culture plastic. All cells of the clonal cell line N2AB-1 attached to Cell-Tak in the presence or absence of fetal calf serum and were found to be resistant to trypsin removal. Conditioned medium from these cells enhanced attachment of N2AB-1 twofold when compared to adherence to tissue-culture plastic. Striking morphological changes were seen in N2AB-1 after culturing on Cell-Tak for 2 days. Thirty percent of the population extended long neurites when grown on Cell-Tak with serum. Without serum, 30 to 50% of the cells extended very broad neurites often branched at the end, which were morphological changes not seen on plastic surfaces. These findings indicate that Cell-Tak is an optimal adhesive for primary neural cell culture and maintenance. Moreover, this adhesive protein appears to induce neuritogenesis and cellular differentiation in a neuronal cell line.

The extracellular matrix of the central and peripheral nervous systems: structure and function

The extracellular matrix (ECM) is the naturally occurring substrate upon which cells migrate, proliferate, and differentiate. The ECM functions as a biological adhesive that maintains the normal cytoarchitecture of different tissues and defines the key spatial relationships among dissimilar cell types. A loss of coordination and an alteration in the interactions between mesenchymal cells and epithelial cells separated by an ECM are thought to be fundamental steps in the development and progression of cancer. Although a substantial body of knowledge has been accumulated concerning the role of the ECM in most other tissues, much less is known of the structure and function of the ECM in the nervous system. Recent experiments in mammalian systems have shown that an increased knowledge of the ECM in the nervous system can lead to a better understanding of complex neurobiological processes under developmental, normal, and pathological conditions. This review focuses on the structure and function of the ECM in the peripheral and central nervous systems and on the importance of ECM macromolecules in axonal regeneration, cerebral edema, and cerebral neoplasia.

Neurite outgrowth from mammalian CNS neurons on astrocytes in vitro may not be mediated primarily by laminin

A number of in vitro studies suggest that certain components of the extracellular matrix (ECM), such as the glycoprotein laminin, can promote neurite outgrowth. In the present study the presence of laminin and heparan sulphate proteoglycan, another ECM molecule, on CNS glial (astrocytes) and non-glial (leptomeningeal) cells in vitro was examined. In addition, the ability of these cells and laminin-coated tissue culture substrates to promote neurite outgrowth from developing mammalian cerebellar cortical neurons was also assayed. Leptomeningeal cells were found to be labelled much more intensely with antibodies against laminin and heparin sulphate proteoglycan than were astrocytes. However, the proportion of neurons extending neurites was fourfold greater on astrocyte monolayers than on leptomeninges, and twofold greater than that on laminin. In addition, the length of the neurites growing on astrocyte monolayers was three- to fourfold greater than that on laminin or leptomeninges. Neurite outgrowth on leptomeninges and laminin could not be enhanced by culturing in astrocyte conditioned medium. The ability of various antibodies to block neurite outgrowth on these monolayers was also studied. These results suggest that the robust neurite outgrowth from mammalian CNS neurons plated on astrocytes may be mediated via an astrocyte surface molecule distinct from laminin.

Glial fibrillary acidic protein, vimentin and fibronectin in primary cultures of human glioma and fetal brain

The expression of glial fibrillary acidic protein (GFAP), vimentin and fibronectin (Fn) was studied in cells cultured from human glioma and fetal brain by indirect immunofluorescence (IIF) microscopy and multiple labelling experiments. In the primary cultures a major part (20%-70%) of the cells usually displayed both GFAP and vimentin and the rest of the cells only vimentin. A prominent variation in GFAP and vimentin fluorescence intensity sometimes made interpretation of double IIF stainings difficult. However, occasional GFAP-positive cells appeared vimentin negative in primary glioma cultures, whereas in fetal brain primary cultures cells that were preferentially GFAP positive also showed at least a weak vimentin immunoreactivity. Only a fraction of the cells, roughly corresponding to the GFAP-negative cells, were Fn positive in the primary cultures. As judged by double IIF, the GFAP-positive cells were usually Fn negative, while the Fn-positive cells were vimentin positive. This could also be demonstrated in triple IIF experiments. During serial subcultivation the amount of cells expressing GFAP decreased, while the number of Fn-positive cells increased. By the third to fourth passage GFAP positivity was usually lost, all cells expressed vimentin and most cells also Fn. The results of the present study demonstrate a general coexpression of GFAP and vimentin in cultured astroglial cells, in addition to cells expressing only vimentin. Interestingly, occasional glioma cells seem to contain GFAP as the only intermediate filament protein as detected by immunocytochemistry.(ABSTRACT TRUNCATED AT 250 WORDS)

Histopathological and immunohistochemical changes in neurosurgically resected epileptic foci

Neurosurgical resection of an epileptic focus was performed in eleven patients suffering from drug resistant focal epilepsy. The clinical result was favourable in nine cases and corresponds to the earlier results. The routinely processed biopsy specimens obtained from the brain resections were stained with haematoxylin-eosin and with specific antisera to GFAP, S-100, NSE, laminin, and fibronectin using the peroxidase-antiperoxidase technique. The main pathological finding was gliosis in eight cases, neuronal degeneration in two cases, and a vascular malformation in one case. The anti-GFAP as a specific marker of astrocytes made the astroglial proliferation clearly visible, demonstrating an astroglial scar in four cases and a moderately to strongly increased amount of astroglial cells in another four cases. Anti-S-100 and anti-fibronectin are not as specific markers. They stained both neurones and glial cells with comparable results to that of anti-GFAP but with a lower specificity and sensitivity. Anti-NSE showed decreased amounts of neurones in most of the heavily gliotic lesions and also stained glial cells in some cases. Anti-laminin stained the pial and vascular basement membranes and revealed an increased vasculature in two cases. From these results, it appears that GFAP immunostaining is a highly demonstrative means for the visualization of astrogliosis in epileptic lesions and may be of help in identifying slight focal changes. An exact demonstration of neuronal loss or other neuronal changes still waits for a more specific marker than NSE. A favourable clinical outcome after neurosurgery seems to be associated with the patients showing a clearly gliotic brain lesion in one temporal lobe.

Leukotriene production by cultured astroglial cells

Astrocytes metabolize arachidonic acid via the cyclooxygenase pathway to prostanoids. We examined whether primary culture astrocytes from neonatal rat brain can be induced to generate and release the lipoxygenase derivative leukotriene C4 (LTC4). While there was only minute constitutive production of immunoreactive LTC4 this metabolite was liberated by astroglial cells in response to calcium ionophore A23187. The phorbol diester 12-O-tetradecanoylphorbol 13-acetate (TPA) failed to precipitate leukotriene release. However, when threshold doses of A23187 were added to astrocyte cultures challenged with TPA, LTC4 was recovered from their supernatants. It is suggested that leukotriene generation by astrocytes bears relevance to immunoinflammatory responses in the central nervous system and may be involved in brain edema formation.

Distribution of laminin and fibronectin along peripheral trigeminal axon pathways in the developing chick

The trigeminal region of the chick was studied with indirect immunofluorescence in order to determine whether extracellular matrix components might be distributed in such a way as to guide trigeminal axons to their peripheral targets in the mandibular arch. Tissue sections from stages 13-15 and 21/22 were immunolabeled indirectly with affinity-purified antibodies raised against fibronectin and laminin, two extracellular matrix glycoproteins that support axon growth in vitro. Fibronectin was distributed ubiquitously throughout the head mesenchyme prior to and during initial axon growth from the brainstem (stages 13-15). Shortly after trigeminal axons reached their target tissues (stage 21/22), fibronectin immunolabeling was distributed throughout the head mesenchyme, but was present only at low levels in the trigeminal ganglion and motor nerve. Laminin immunolabeling was distributed in the lateral head mesenchyme at stage 13 as small specks and patches. At stage 14, when the motor axons first exit from the brainstem, short, linear arrays of laminin immunostaining were present from the basement membrane of the neural tube to the core of the mandibular arch, and many were parallel to the direction of axon growth. By stage 21/22 the trigeminal ganglion and motor root showed intense antilaminin immunofluorescence as did the central core of the mandibular arch. These studies suggest that the distribution of fibronectin within the head mesenchyme cannot give directional information to the growing trigeminal axons because of its homogeneous distribution. However, the initial distribution of laminin during the earliest stages of axon outgrowth may provide an extracellular matrix pathway that permits trigeminal axons to reach their targets.

Retinal ganglion cell survival and neurite regeneration requirements: the change from Müller cell dependence to superior colliculi dependence during development

A study has been made of the effects of Müller conditioned media or neonatal superior collicular extracts on the survival in dissociate culture of retinal ganglion cells (RGC) from differently aged rats. Embryonic and neonatal RGC were identified either by retrograde horseradish peroxidase (HRP) or Thy-1 antibody labelling techniques. Müller conditioned media supported the survival, over 24 h in culture, of 85% of the RGC plated from 17-day embryos (E17); in contrast, superior collicular extract only maintained 45% of these RGC. With further development there was a decline in the survival enhancing effects of the Müller conditioned media and an increase in the survival due to superior collicular extracts: by postnatal day 12 (P12), the survival of RGC had declined to 20% in the Müller media, but had increased to over 90% in the colliculus extract. This transition in the dependence of RGC from Müller cells to superior colliculi was examined with homogeneous cultures of RGC, obtained using cell sorting techniques. RGC in these cultures showed the same transition in dependence from Müller cells to superior colliculi, indicating that the survival-enhancing effects were not mediated by the other intrinsic cells of the retina. The results suggest that the survival of RGC is at first dependent on the intrinsic glia of the retina and only later, as development proceeds, on the targets of the RGC in the superior colliculus. The normal RGC death period in the rat extends from near birth to about 6 days postnatal. The question then arises as to the timing of trophic support from Müller glia and from neurones in the tectum in relation to the duration of the normal RGC death period. This has been examined in the present work.

Distribution of extracellular matrix proteins in primary human brain tumours: an immunohistochemical analysis

Using immunohistochemical techniques, we localized several glycoproteins of the extracellular matrix in paraffin-embedded sections of 4 normal brain and 38 primary intracranial tumour specimens. All specimens were positively immunostained to various degrees by monoclonal antibodies to type IV collagen and procollagen III and by antisera to laminin and fibronectin. Staining was consistently most intense at sites of contact between neuroepithelial and mesenchymal or leptomeningeal elements; there was no demonstrable staining within or between neuroepithelial elements in the neuropil. Tumour cells from meningiomas and from the sarcomatous portion of a gliosarcoma were positively immunostained for fibronectin and laminin. The integrity of the glial limitans externa was demonstrated by the positive linear reaction product produced by immunostains for type IV collagen and laminin, even in the most malignant gliomas. The deposition of extracellular matrix glycoproteins at the glial-mesenchymal interface observed in this study of primary human brain tumours is a manifestation of one of the interactions between tumour and stromal cells in the central nervous system. A loss of coordination and an alteration in the interactions between epithelial cells and stromal cells across extracellular matrices such as basement membranes are thought to be fundamental steps in the development and progression of cancer. Further characterization studies focusing on other markers of the extracellular matrix are needed to elucidate completely the function of this structure in the central nervous system.

Procedure for establishing oligodendroglial cells in primary cultures based on developmental parameters

We have established cultures using dissociated cells obtained from the neopallium of mouse pups at several different stages of development. The cellular composition of these cultures changed from more than 95% astrocytes when cultures were established from the neopallium of neonates to more than 90% oligodendrocytes when cultures were established from the neopallium of 2-week-old pups. The oligodendrocytic nature of the cells was established on morphological bases as well as the presence of an oligodendrocytic marker, galactocerebroside.

Light microscopic immunolocalization of laminin, type IV collagen, nidogen, heparan sulphate proteoglycan and fibronectin in the enteric nervous system of rat and guinea pig

The localization of the extracellular matrix components laminin, fibronectin and type IV collagen in the enteric nervous system and the surrounding smooth muscle was investigated by immunohistochemical methods, using tissue sections of rat and guinea pig large intestine. None of these molecules were detectable inside the enteric ganglia. In contrast, they were easily demonstrable in association with the basement membrane of satellite cells within sensory and sympathetic ganglia. All of these molecules were, however, present in or nearby the basement membrane that surrounds each enteric ganglion. This agrees with previous ultrastructural observations that, in small mammals, neither basement membranes nor large connective tissue spaces are found inside enteric ganglia. The matrix molecules under study were also detected in the basement membrane of the nearby smooth muscle cells that make up the muscle layer of the gut wall. Fibronectin was frequently observed as a broad staining pattern suggesting its localization in the lamina reticularis rather than in the lamina densa. In addition, nidogen and heparan sulphate proteoglycan were demonstrated in the basement membrane of both enteric ganglia and Schwann cells.

Heterogeneity of a cultured neoplastic glial line. Establishment and characterisation of six clones

Six clones have been established from a tumorigenic glial cell line (VMDk P497) originally derived from a spontaneous mouse astrocytoma. The clones express dissimilar morphological, antigenic, kinetic and chromosomal properties, thereby indicating the heterogeneity of the parent culture line.

The K.G. McKenzie award lecture--1986. Effects of extracellular matrix proteins on the growth and differentiation of an anaplastic glioma cell line

Efforts to determine the factors responsible for reversing malignancy in the central nervous system may not only increase our understanding of the growth of primary human brain tumors, but may eventually prove to be of therapeutic benefit as well. We therefore devised a model system to study the effects of extracellular matrix (ECM) proteins on the malignant phenotype of an anaplastic glioma line, U-343 MG-A. Well-characterized cultures derived from normal human leptomeninges were grown to confluence and maintained for 2 weeks. The pia-arachnoid cells were then removed with detergent and base, leaving behind an ECM enriched in laminin, fibronectin, types I and IV collagen, and procollagen III. U-343 MG-A tumor cells planted on top of this normal ECM were profoundly growth inhibited, developed multiple slender cytoplasmic processes similar to those of normal astrocytes, and expressed more GFAP per cell than did tumor cells growing on plastic alone. The growth of U-343 MG-A tumor cells in flasks coated with purified fibronectin or laminin was not significantly inhibited. However, U-343 MG-A cultures grown in flasks coated with type I or IV collagen showed decreased cellular proliferation and altered cell morphology. Conditioned medium from U-343 MG-A tumor cells growing on plastic alone contained a 64 kD activated metalloprotease. U-343 MG-A tumor cells growing on the pia-arachnoid ECM do not demonstrate such proteolytic activity. We conclude that the tumor cell microenvironment is extremely important in modulating the growth and differentiation of an anaplastic glioma cell line.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of transformation on the expression of laminin and fibronectin by neural cells

We have studied laminin and fibronectin expression in a collection of rat cerebellar neural cell lines transformed with a mutant of Rous sarcoma virus which is temperature sensitive for transformation. We show that regardless of their neuronal or glial properties the cell lines produce both laminin and fibronectin. Laminin is expressed in similar amounts in cell lines grown at either the permissive or nonpermissive temperature for transformation, while fibronectin is generally expressed at higher levels in cells kept at the nonpermissive temperature. To provide further evidence that neural cells can produce laminin and fibronectin, double label immunofluorescence studies were conducted on primary cerebellar cultures. Both laminin and fibronectin were found to be present in the primary culture, and laminin was found to be associated with a subpopulation of astrocytes.

Retinal ganglion cell survival requirements: a major but transient dependence on Müller glia during development

Neonatal rat retinal ganglion cells (RGC), identified by a retrograde horseradish peroxidase labelling technique, survived over a 16-h culture period when cultured on monolayers of rat Müller glia or in conditioned media derived from these cells. Maximal survival of neonatal RGC was obtained at 1:4 dilution of conditioned media. However, extensive neurite outgrowth from RGC was seen only when they were cultured on glial monolayers. Homogeneous cultures of RGC, obtained using cell sorting techniques, also survived in Müller-conditioned media. This indicates that other intrinsic cells of the retina do not mediate the effect of Müller-conditioned media on RGC. Conditioned media from Müller glia do not significantly enhance the survival of RGC from 6 day retinae. However, these older RGC are supported in culture by extracts derived from their target tissue. These results suggest that as development proceeds RGC survival is dependent on factors produced by target rather than those produced by Müller glia.

Comparison of astrocytic morphology, proliferation, marker profile and response to neurons in wild-type and weaver mutant mouse cerebella in culture

In serum-free monolayer cultures of early postnatal weaver (wv/wv) cerebellum granule neurons show decreased attachment, survival and neurite outgrowth when compared to wild-type (+/+) littermate cultures. wv/wv Astrocytes display a more epithelioid morphology and altered proliferation. However, both morphology and proliferation of wv/wv astrocytes were reversed to a normal phenotype by addition of purified small neurons from early postnatal cerebella from +/+ animals. Attachment of +/+ neurons to wv/wv astrocytes was not significantly different from that of +/+ astrocytes and antigenic marker profiles of wv/wv and +/+ astrocytes differed only slightly. Attempts failed to revert the abnormal wv/wv phenotype in neurons by addition of gangliosides, triiodothyronine T3, prostaglandin A2, medium containing 1% horse serum, conditioned medium from +/+ cerebellar cultures, or by cocultivation with +/+ astrocytes. We would like to suggest that the primary defect of the wv/wv mutation is predominantly an abnormality in granule cell neurons, but not of the vast majority of astrocytes.

Immunocytochemically defined astroglia from fetal, newborn and young adult rats express beta-adrenergic receptors in vitro

Autoradiography of radioligand binding was used to assess the expression of beta-adrenergic receptors (beta-AR) by immunocytochemically identified astroglia cultured from the cerebral cortices of rats 16 days in gestation through 28 days postnatal (DPN). Polygonal astroglia isolated from animals at each age examined were found to exhibit large numbers of beta-AR. In contrast, only low levels of beta-AR could be detected on process-bearing astroglia and fibroblasts. Quantitative analysis showed that there was an increase in the density of beta-AR on polygonal astroglia between 16 days in gestation and 1 DPN. This increase in beta-AR receptor density was present whether the cells were grown for long periods of time in culture (8-22 days) or for short periods of time in culture (1-5 days). The results also suggest that differences in the level of receptor expression between cells grown in short-term and long-term culture may be due in part to culture methodology.

Immunocytochemical characterization of the A15 A5 transplantable brain tumour model in vivo

A comparative immunocytochemical study was carried out on intracerebral and extracranial gliomas of the rat produced by intracerebral injection of low (10th) and high (40th) in vitro passages of neoplastic glial cells. The cells injected were a neoplastic astrocytic clone-A15 A5-derived from a mixed glioma induced transplacentally by N-ethyl-N-nitrosourea (ENU) in a BD-IX rat. An inverse relationship was seen between the expression of the astrocytic markers glial fibrillary acidic protein (GFAP) and glutamine synthetase (GS) at low and high passage: GFAP decreased with increasing passage while GS increased. The distribution of vimentin, the major cytoskeletal component of immature glia, was constant, irrespective of passage--a feature consistent with previous in vitro findings. The expression of laminin by both reactive and neoplastic astrocytes increased with increasing passage, while high magnification examination revealed the presence of the glycoprotein fibronectin on the cell-surfaces of A15 A5-derived tumour cells. Both neoplastic and reactive astrocytes expressed S-100 protein with a higher proportion of positive cells in extracranial tumours. Occasional cells, probably actively phagocytizing populations of reactive astrocytes and macrophages, were positive for alpha-1-antitrypsin. None of the neoplastic cells expressed the oligodendrocyte marker carbonic anhydrase II. This immunocytochemical study supports previous morphological findings in differences in differentiation between the cells of tumours produced by high and low passage cells.

Fibronectin is expressed by astrocytes cultured from embryonic and early postnatal rat brain

In early primary cultures from newborn rat brain, few glial fibrillary acidic protein (GFAP)-positive glial cells expressed intracytoplasmic immunoreactivity for fibronectin. After the second week in culture, however, fibronectin was expressed by a distinct population of GFAP-positive flat astrocytes, irrespective of which brain region was studied. In cerebellar cultures, these cells were more abundant than in cortical or neostriatal cultures and often formed a major population of the GFAP-positive cells. The difference in fibronectin expression between cerebellum and the other areas studied was statistically significant. When cultures were started from 9-day-old postnatal rat brain, fibronectin-positive astrocytes appeared earlier than in those from newborn animals, in all areas studied. Further, especially in the case of cerebellum, the number of fibronectin-positive astrocytes increased as a function of time in culture. In cultures started from whole brains of 12-day-old rat embryos, fibronectin was expressed within 24 h in culture by all the cells with morphology of flat astrocytes, positive for vimentin but negative for GFAP. These results indicate that astrocytes cultured from newborn and early postnatal rat brain are a heterogeneous population of cells: depending on the brain region studied and also depending on the age of brain tissue or the time in culture, less than 1-60% of the GFAP-positive flat astrocytes expressed fibronectin. This, together with the fact that fibronectin was present in early embryonic brain cells in culture, suggests that fibronectin may be a prerequisite for the development or interactions of brain cells.

Immunocytochemical characterization of neuron-rich primary cultures of embryonic rat brain cells by established neuronal and glial markers and by monospecific antisera against cyclic nucleotide-dependent protein kinases and the synaptic vesicle protein synapsin I

Primary cell cultures derived from embryonic rat brain were characterized by immunocytochemical methods using established cell markers and monospecific antisera against cyclic nucleotide-dependent protein kinases and the synaptic vesicle protein, synapsin I. The cultures contained predominantly neurons, few astroglial cells and no oligodendroglial cells, based on immunocytochemical studies of the distribution of neuron-specific enolase, glial fibrillary acidic protein, myelin basic protein and galactocerebroside. Subsequently, the immunocytochemical localization of synapsin I, the cyclic GMP-dependent protein kinase and the various subunits of cyclic AMP-dependent protein kinase was determined. Synapsin I, a substrate for both the cyclic AMP- and Ca2+/calmodulin-dependent protein kinases, appeared particularly useful as a specific neuronal marker in primary cultures. Both immunocytochemical and immunoblotting techniques readily detected synapsin I in neuron-rich embryonic brain cultures, but indicated that synapsin I was absent from glia-rich primary cultures of newborn rat brain cells which lacked neurons. The intracellular localization of synapsin I in neurons changed markedly during the time of cell culture. In the first 10 days of cell culture, synapsin I appeared to be confined to neuronal cell bodies, whereas later it shifted to a patchy distribution in neuronal processes, perhaps indicating the transport of synapsin I in synaptic vesicles from the compartment of protein synthesis to its final synaptic location. Within neuron-rich embryonic cultures, the regulatory subunit (R-II) and the catalytic subunit (C) of cyclic AMP-dependent protein kinase appeared to be highly concentrated in neurons examined immunocytochemically. However, biochemical experiments demonstrated that R-II and C were also present in non-neuronal cell types of brain cell primary cultures. Cyclic GMP-dependent protein kinase, a marker protein for cerebellar Purkinje cells and for smooth muscle cells, was not detected immunocytochemically in neuron-rich cultures of embryonic brain cells, suggesting that Purkinje cells and smooth muscle cells were either absent from or not sufficiently developed in these cultures.

Normal and malignant neural cells: a comprehensive survey of human and murine nervous system markers

Tumor-associated neural markers are finding increased application in diagnostic histopathology and in the development of brain tumor therapy. The major cell-type-specific markers and monoclonal antibodies that identify murine and human neural cells are reviewed in this study. Monoclonal antibodies, raised against fetal and adult neural tissue, neuroectodermal tumor tissue, or cell line immunogens which recognize epitopes on brain tumors are comprehensively described including antigens common to the nervous, hematopoietic, and immune systems. The clinical application of neural cell markers and monoclonal antibodies for the diagnosis, localization, and treatment of neuroectodermal tumors is reviewed.

Neuronal influence on antigenic marker profile, cell shape and proliferation of cultured astrocytes obtained by microdissection of distinct layers from the early postnatal mouse cerebellum

To study the cellular heterogeneity of astrocytes from early postnatal mouse cerebellum in culture, Bergmann glia were enriched by hand-dissection of Purkinje, molecular and external granular layers ('outer' layer) and fibrous astrocytes of white matter and deep cerebellar nuclei ('inner' layer). Both populations of GFA protein and vimentin-positive astrocytes express N-CAM and the L2/HNK-1 epitope, but not tetanus toxin receptors or A2B5 antigen, at levels detectable by indirect immunofluorescence procedures. The two astrocyte populations are thus indistinguishable from each other. Expression of tetanus toxin receptors and A2B5 antigen in these astrocytes can, however, be induced by removal of neurons. The expression of tetanus toxin receptors is again reduced by readdition of purified populations of small cerebellar neurons. Morphology and proliferation of astrocytes from both layers is also dependent on the presence of neurons: removal of neurons leads to an epithelioid, rather than star-shaped morphology and a severalfold increase in proliferation. Readdition of neurons induces astrocytes to return to their star-shaped morphology. Epidermal growth factor increases proliferation in both populations of astrocytes. We conclude that neither antigenic marker profile, morphology nor proliferative responses serve to distinguish between enriched Bergmann glia and enriched fibrous astrocytes.

Cell type specificity and developmental expression of the L2/HNK-1 epitopes in mouse cerebellum

The developmental expression of carbohydrate epitopes recognized by monoclonal antibodies HNK-1 and L2 was studied in tissue sections and cultures of mouse cerebellum. At all ages studied the 2 antibodies had identical staining patterns. In cultures of embryonic and early postnatal mice some, but not all cells of all 3 major neural cell types, neurons, astrocytes and oligodendrocytes, but not fibronectin-positive fibroblast-like cells were labeled by the antibodies. The most intensely labeled cells were those with antigenic marker profiles characteristic of immature glia. L2/HNK-1 epitope expression on neuron precursors was detected most convincingly in sections, where the band of migrating granule cell precursors in the external granular layer of the embryo and outer part of the external granular layer at early postnatal ages were strongly labeled by the antibodies. In sections of adult cerebella an overall reduced, but detectable level of L2/HNK-1 epitope expression was seen in all layers, but slightly more prominently in granular layer and white matter. At embryonic ages ventricular cells did not express detectable levels of epitopes. Most of the present data support the notion that the L2/HNK-1 epitopes are most strongly expressed on cell types with properties of glial and neuronal precursor cells.

Immunocytochemical demonstration of glial-neuronal interactions and myelinogenesis in subcultures of rat brain cells

Subcultures have been established from primary rat brain cell cultures and have been characterised with a range of cell-specific immunocytochemical markers. The subcultures are mainly composed of fibrous astrocytes, oligodendrocytes and neurones. The cells do not divide to any great extent giving a system where it is possible to follow culture development at the cellular level for a number of weeks. During this time oligodendrocytes colonise subpopulations of neurones, differentiate further showing the presence of myelin basic protein and elaborate myelin-like membrane; the fibrous astrocytes remain scattered uniformly throughout the cultures. Radially oriented processes emerge from the oligodendrocyte-neurone aggregates which subsequently coalesce to form fascicles that link the clusters of cells together. These fascicles react with antibodies for both neurofilament protein and myelin basic protein. The subcultures provide a straightforward system that is composed of cells derived entirely from the CNS, is free from mitotic inhibitors and yet retains a sufficiently low cell density to allow immunocytochemical identification of the cell types present. The subcultures should be useful for the study of trophic interactions between oligodendrocytes and neurones as well as the early events associated with myelinogenesis.