Astrocytes and oligodendrocytes in dissociated cell culture of adult rat optic nerve

Antitumor Effects of 5-Aminolevulinic Acid on Human Malignant Glioblastoma Cells

5-Aminolevulinic acid (5-ALA) is a naturally occurring non-proteinogenic amino acid, which contributes to the diagnosis and therapeutic approaches of various cancers, including glioblastoma (GBM). In the present study, we aimed to investigate whether 5-ALA exerted cytotoxic effects on GBM cells. We assessed cell viability, apoptosis rate, mRNA expressions of various apoptosis-related genes, generation of reactive oxygen species (ROS), and migration ability of the human U-87 malignant GBM cell line (U87MG) treated with 5-ALA at different doses. The half-maximal inhibitory concentration of 5-ALA on U87MG cells was 500 μg/mL after 7 days; 5-ALA was not toxic for human optic cells and NIH-3T3 cells at this concentration. The application of 5-ALA led to a significant increase in apoptotic cells, enhancement of Bax and p53 expressions, reduction in Bcl-2 expression, and an increase in ROS generation. Furthermore, the application of 5-ALA increased the accumulation of U87MG cells in the SUB-G1 population, decreased the expression of cyclin D1, and reduced the migration ability of U87MG cells. Our data indicate the potential cytotoxic effects of 5-ALA on U87MG cells. Further studies are required to determine the spectrum of the antitumor activity of 5-ALA on GBM.

Life under pressure: The role of ocular cribriform cells in preventing glaucoma

Primary open-angle glaucoma is a multifactorial blinding disease often impacting the two pressure-sensitive regions of the eye: the conventional outflow pathway and the optic nerve head (ONH). The connective tissues that span these two openings in the globe are the trabecular meshwork of the conventional outflow pathway and the lamina cribrosa of the ONH. Resident cribiform cells of these two regions are responsible for actively remodeling and maintaining their connective tissues. In glaucoma, aberrant maintenance of the juxtacanalicular tissues (JCT) of the conventional outflow pathway results in ocular hypertension and pathological remodeling of the lamina cribrosa results in ONH cupping, damaging retinal ganglion cell axons. Interestingly, cells cultured from the lamina cribrosa and the JCT of the trabecular meshwork have similarities regarding gene expression, protein production, plus cellular responses to growth factors and mechanical stimuli. This review compares and contrasts the current knowledge of these two cell types, whose health is critical for protecting the eye from glaucomatous changes. In response to pressure gradients across their respective cribiform tissues, the goal is to better understand and differentiate healthy from pathological behavior of these two cell types.

Plate reader-based cell viability assays for glioprotection using primary rat optic nerve head astrocytes

Optic nerve head astrocytes (ONHAs) are the major glia cell type in the non-myelinated optic nerve head where they contribute critically to extracellular matrix synthesis during development and throughout life. In glaucoma, and in related disorders affecting the optic nerve and the optic nerve head, pathological changes include altered astrocyte gene and protein expression resulting in their activation and extracellular matrix remodeling. ONHAs are highly sensitive to mechanical and oxidative stress resulting in the initiation of axon damage early during pathogenesis. Furthermore, ONHAs are crucial for the maintenance of retinal ganglion cell physiology and function. Therefore, glioprotective strategies with the goal to preserve and/or restore the structural and functional viability of ONHA in order to slow glaucoma and related pathologies are of high clinical relevance. Herein, we describe the development of standardized methods that will allow for the systematic advancement of such glioprotective strategies. These include isolation, purification and culture of primary adult rat ONHAs, optimized immunocytochemical protocols for cell type validation, as well as plate reader-based assays determining cellular viability, proliferation and the intracellular redox state. We validated and standardized our protocols by performing a glioprotection study using primary ONHAs. Specifically, we measured protection against exogenously-applied oxidative stress using tert-butylhydroperoxide (tBHP) as a model of disease-mediated oxidative stress in the retina and optic nerve head by the prototypic antioxidant, 6-hydroxy-2,5,7,8-tetramethylchroman-2-carboxylic acid (Trolox). Levels of oxidative stress were increased in the response to exogenously applied tBHP and were assessed by 6-carboxy-2', 7' dichlorodihydrofluorescein diacetate (DCFDA) fluorescence. Normalized DCFDA fluorescence showed a maximal 5.1-fold increase; the half-maximal effect (EC50) for tBHP was 212 ± 25 μM. This was paralleled very effectively in the assays measuring cell death and cell viability with half-maximal effects of 241 ± 20 μM and 194 ± 5 μM for tBHP in the lactate dehydrogenase (LDH) release and the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) conversion assays, respectively. Pre-treatment with 100 μM Trolox decreased the sensitivity of ONHAs to tBHP. Half-maximal effects increased to 396 ± 12 μM tBHP in the LDH release assay and to 383 ± 3 μM tBHP in the MTT assay. Vehicle treatment (0.1% v/v ethanol) did not significantly affect cellular responses to tBHP. Antioxidant treatment increases ONHA viability and reduces the deleterious effects of oxidative stress. Our experiments provide important feasibility data for utilizing primary rat ONHAs in plate reader-based assays assessing novel therapeutics for glioprotection of the optic nerve and the optic nerve head in glaucoma and related disorders. Furthermore, our novel, standardized protocols have the potential to be readily adapted to high-throughput and high-content testing strategies.

The virion host shutoff protein of herpes simplex virus type 1 has RNA degradation activity in primary neurons

The virion host shutoff protein (Vhs) of herpes simplex virus type 1 induces destabilization of mRNA following infection. Our study of primary neurons from CD-1 mice demonstrates that vhs is functional in neurons but that more Vhs is required to mediate RNA degradation in neurons than in other susceptible cells.

Central nervous system lesions that can and those that cannot be repaired with the help of olfactory bulb ensheathing cell transplants

Growth-promoting macroglia (aldynoglia) with growth properties and immunological markers similar to Schwann cells, are found in loci of the mammalian CNS where axon regeneration occurs throughout life, like the olfactory sytem, hypothalamus-hypophysis and the pineal gland. Contrary to Schwann cells, aldynoglia mingle freely with astrocytes and can migrate in brain and spinal cord. Transplantation of cultured and immunopurified olfactory ensheathing cells (OECs) in the spinal cord after multiple central rhizotomy, promoted sensory and central axon growth and partial functional restoration, judging by anatomical, electrophysiological and behavioural criteria. OEC transplants suppressed astrocyte reactivity, thus generally favouring axon growth after a lesion. However, the functional repair promoted by OEC transplants was partial in the best cases, depending on lesion type and location. Cyst formation after photochemical cord lesion was partially prevented but neither the corticospinal tract, interrupted by a mild contusion, nor the sectioned medial longitudinal fascicle, did regrow after OEC transplantation in the injured area.

Schwann-like macroglia in adult rat brain

Olfactory ensheathing cells (OECs) share properties with astrocytes and Schwann cells. This study was designed to test the hypothesis that glia with properties similar to those exhibited by OECs might be present in brain areas other than the olfactory bulb. We found tanycytes and pituicytes to express a distinctive set of immunological markers in common with OECs and nonmyelinating Schwann cells, namely low-affinity neurotrophin receptor (p75NTR), O4 antigen, estrogen receptor-alpha type, and insulin-like growth factor 1 (IGF-1). The two glial types could be cultured from adult hypothalamus and neurohypophysis, respectively, using the methods developed for olfactory OECs. Both glial types displayed morphologies reminiscent of Schwann cells, in primary culture. Schwann-like central glia presented a preferred growth substrate for dorsal root ganglion neurites and, when making intimate contacts with them, manifested a myelinating phenotype. These combined properties define a type of CNS macroglia that would not fit within conventional central glia types.

Estrogen receptor immunoreactivity in Schwann-like brain macroglia

Olfactory ensheathing cells, tanycytes, pituicytes, pineal glia, retinal Müller cells, and Bergmann glia of normal male rats express concomitantly estrogen receptor, low-affinity neurotrophin receptor, antigen O4, and GFAP, markers characteristic of nonmyelinating Schwann cells. These cells were able to survive and proliferate when cultured from adult tissue, promoted neurite outgrowth, and could guide and ensheath growing neurites. We called this distinct group of growth-promoting central nervous system (CNS) macroglia aldynoglia (Greek: to make grow). Its proliferative and growth-promoting properties seem to be retained during the whole lifetime of the organism in those CNS loci where normal function depends on continuous axon renewal. Aldynoglia plasticity seems totally or partially lost with age where and when it is no longer critical, as in the case of adult cortical and spinal cord radial glia. The concomitant expression of estrogen receptor and low-affinity neurotrophin receptor may promote Schwann-like plasticity of glial cells.

Reactive astrocytes in explant cultures of glial scars derived from lesioned rat optic nerve: an ultrastructural study

Explant cultures of glial scars generated by surgical removal of the retina in 3-60-day-old rats were used to determine if reactive astrocytes survive in vitro and how closely reactive astrocytes in culture resemble their in vivo counterparts. Characterization of the composition of age matched glial scars in vivo and in vitro showed that reactive astrocytes survived in glial scar explants even after several weeks in culture. Reactive astrocytes in both neonatal and adult glial scars retained ultrastructural features characteristic of reactive astrocytes in vivo. However, fewer reactive astrocytes survived in culture when explants were prepared from adult rat glial scars. The results of this study demonstrate that tissue culture is a viable model for the study of reactive astrocytes. A critical factor in the survival of reactive astrocytes in culture was the complete removal of myelin debris prior to the establishment of the culture. This outcome suggests that it will be important to clarify why myelin debris persists in culture and how it affects the survival of reactive astrocytes.

Preparation and characterization of type 1 astrocytes cultured from adult rat cortex, cerebellum, and striatum

Astrocytes have been prepared from adult rat cortex, cerebellum, and striatum, using a modification of the McCarthy-DeVellis (J Cell Bio 85:890, 1980) method. The cultures consist of 99% type 1 polygonal astrocytes, which divide more slowly than cells from newborn animals. One day after preparing the cultures, 90% of the cells are glial fibrillary acidic protein (GFAP)-positive and 80% are vimentin-positive by immunohistochemical staining, suggesting that they are present de novo and not derived from precursor cells. The astrocytes from adult brain respond to an elevation of intracellular cyclic AMP, following treatment with forskolin, by becoming more stellate in shape and putting out fine ramified processes. They contain the same amount of GFAP per mg protein, measured by immunoblot, as cells from newborn animals. These cultures thus offer the possibility of comparing the biochemical properties of astrocytes derived from adult animals with those from newborn animals, or with cultures of reactive astrocytes isolated from lesioned brain.

Neurobiology of human oligodendrocytes in culture

Enriched populations of oligodendrocytes were isolated from adult human brains of 3-15 hours postmortem using the trypsinin digestion-Percoll density gradient method and were cultured for an extended period of time up to 6 months. Cell type specific antigens that were expressed by oligodendrocytes were galactocerebroside, myelin basic protein, proteolipid protein, 2'3'-cyclic nucleotide 3'-phosphohydrolase and myelin-associated glycoprotein. In addition, HLA-A,B,C and HLA-DR, respectively, Class I and Class II antigens of the major histocompatibility complex, were demonstrated on oligodendrocytes. Three classes of gangliosides, GM1, GM4, and GD3, were also demonstrated on oligodendrocytes, while GM1 and GM4 gangliosides were detected on the surface of astrocytes. The presence of "transitional" or "bipotential" glial cells that were derived from oligodendrocytes and that expressed both oligodendroglial and astrocytic phenotypes was demonstrated. Treatment of the cells by cyclic AMP and its derivatives reversed this dual phenotypic expression back to the oligodendroglial trait. Electron microscopic examination of oligodendrocytes indicated that they were capable of synthesizing and assembling myelin sheaths in culture in the absence of any neuronal signal input.

Primary culture of astrocytic glial cells from rainbow trout, Salmo gairdneri L., brain

A method is described for the preparation and maintenance of rainbow trout brain astrocytes in primary culture. A dissociated cell suspension was prepared from brains from young fish by mechanical sieving through nylon guazes, and the cells cultured in polylysine-treated plastic tissue culture flasks at 22 degrees C. The resultant cultures were characterised by specific immunofluorescent staining using glial fibrillary acidic protein (GFAP) for astrocytes and Thy 1 for fibroblastic cells. The cultures were greater than 95% astrocytes with fibroblasts the only other cell type present. These highly enriched astrocyte cultures provide a unique system for various neurochemical, neurophysiological and biochemical studies of fish neural cells. Polyunsaturated fatty acid metabolism will be an area of particular interest.

Immunocytochemical characterization of primary glial cell cultures from normal adult human brain

Primary cultures were established from autopsy or biopsy samples of normal adult human brain and characterized by immunocytochemical techniques. Initially, macrophages were the predominant cell type adhering to the substratum, but as their number fell that of glial cells increased. Oligodendrocytes comprised 30% of the glial population in white matter cultures, and their perikarya and elongated processes were immunostained with antibodies directed against galactocerebroside and four myelin proteins. In white and grey matter cultures, process-bearing astrocytes and small numbers of polygonal astrocytes were stained with antibodies against glial fibrillary acidic protein and glutamine synthetase. Fibroblasts started to appear at 3 weeks and proliferated to form a monolayer beneath glial cells by 5 weeks. Glia began to die in the 6th week. These primary cell cultures of white or grey matter can be used to study the properties of glial cells from normal or pathological adult human brain.

Neither laminin nor prior optic nerve section are essential for the regeneration of adult mammalian retinal ganglion cell axons in vitro

Retinal explants obtained from normal adult rats and from operated animals in which the optic nerve had been sectioned 10 days previously were cultured in either serum-containing or serum-free medium on poly-L-lysine and laminin substrata. Regenerating ganglion cell axons growing from these explants have been identified using monoclonal antibodies against Thy-1.1 cell surface glycoprotein and the 200-kDa subunit neurofilament protein. Irrespective of substratum or medium composition, axons regenerated from 28-49% of normal rat retinal explants. This percentage increased to 60-84% of explants from operated rats. There were no significant differences in percentages of explants from normal or operated rats showing neurite outgrowth when substrata of either poly-L-lysine or laminin were compared in serum-free medium. In serum-containing medium the results were less easily interpreted due to the presence of an outgrowth of non-neuronal (glia and mesenchymal) 'flat cells', which served as a preferred axonal substratum in many cases. Thus we show that adult rat retinal ganglion cell axons will regrow in vitro, and that a 'priming' optic nerve section will increase this response. In neither case is the response laminin-dependent.

Pure astrocyte cultures derived from cells isolated from mature brain

Enriched preparations of oligodendrocytes, isolated either from adult bovine brain or from 30-day-old rat brain, eventually yield cultures in MEM-15% calf serum that contain, in addition to oligodendrocytes, proliferating astrocytes and variable numbers of fibroblast-like cells. If these cultures are switched to a serum-free defined medium during the 1st week, mixed cultures containing only oligodendrocytes and astrocytes are obtained. Bovine cultures can be replated and purified by selective adhesion to yield cultures that are greater than 99% astrocytes; similar procedures were not successful with rat cultures. Cytoskeletal preparations of the purified astrocyte cultures from mature bovine brain contain both vimentin and glial fibrillary acidic protein (GFAP), but vimentin is by far the major intermediate filament protein. Thus, the intermediate filament composition of these astrocytes is similar to that of astrocytes in primary cultures obtained from neonatal rat brain. Immunofluorescent studies of these cultures at 24 hr in vitro show that there are no GFAP+ cells in cultures of either species; the bovine cultures contain greater than 95% GC+ cells; and the rat cultures contain 90% GC+ cells. After a few days in vitro flat cells appear that are vimentin+/GFAP-/GC-. In serum-free medium these cells eventually become vimentin+/GFAP+. We propose that the astrocytes that grow in these cultures arise from a population of glial precursor cells, which are present even in adult brain and are isolated together with oligodendroglia, and that they do not derive from contaminating mature astrocytes. Thus, the astrocytes in our cultures may have the same origin as astrocytes grown in culture from dissociated neonatal brain.

Is Thy-1 expressed only by ganglion cells and their axons in the retina and optic nerve?

The distribution of Thy-1 in the retina and optic nerve has been examined immunohistochemically, and compared to that of the astrocytic marker glial fibrillary acidic protein. The axons and cell bodies of ganglion cells were found to be Thy-1 positive as were processes within the inner plexiform layer. Transection of the optic nerve in the neonatal rat results in the rapid degeneration of the ganglion cells but some Thy-1 staining remains in the inner plexiform layer. We have estimated using an immunoassay of normal and optic nerve transected retinae that about 70% of the Thy-1 in the retina is on ganglion cells and their axons and the remainder is on cells which contribute processes to the inner plexiform layer, presumably amacrine, bipolar or Müller cells. In the optic nerve the Thy-1 was found to be limited to the fascicles of optic nerve fibres and the intrafascicular spaces, containing astrocytes and their processes, were not stained. Axotomy of the adult nerve, which produced axonal degeneration and astrocytic proliferation, led to a loss of over 95% of the Thy-1 from the nerve. We found no evidence that the astrocytes of the retina or optic nerve were Thy-1 positive in normal animals or during degeneration.

Cultured human and rat oligodendrocytes and rat Schwann cells do not have immune response gene associated antigen (Ia) on their surface

In order to determine if oligodendrocytes or Schwann cells had surface immune response gene associated antigen (Ia), we studied the binding of: (a) mouse monoclonal antibodies to rat Ia, to cultures of rat oligodendrocytes and Schwann cells; and, (b) mouse monoclonal antibodies to human Ia, to cultures of human oligodendrocytes employing radioimmunoassay and indirect immunofluorescence. Cells were identified using phenotypic markers; rabbit anti-galactocerebroside (GalC) for oligodendrocytes; rabbit anti-GalC and rabbit anti-Schwann cell for Schwann cells; rabbit anti-glial fibrillary acidic protein for astrocytes; rabbit anti-fibronectin for fibro-blasts and leptomeningeal cells, and the capacity to ingest latex particles for macrophage-microglia. Ia could not be detected on the surface of oligodendrocytes, Schwann cells, astrocytes, fibroblasts, or leptomeningeal cells. A small number of latex ingesting cells bound anti-Ia even after blocking of surface Fc receptors.

The distribution of Thy-1 antigen in the P.N.S. of the adult rat

The distribution of the cell surface glycoprotein Thy-1 in the P.N.S. of adult rats was examined using immunohistochemical and experimental techniques. In the hypoglossal nerve the pattern of Thy-1 labelling suggested the antigen was on the plasma membrane of all axons, not only in their major myelinated course but also on their fine terminal branches and at the motor end plate itself. Similarly in other peripheral nerves examined [phrenic and vagus nerves, dorsal and ventral roots, and both the preganglionic and postganglionic trunks of the superior cervical ganglion (SCG) and the submandibular ganglion] Thy-1 was always associated with axons, but the resolution obtained with immunohistochemical techniques was not in itself sufficient to exclude the possibility that the antigen was on the surface of the ensheathing Schwann cell where it apposed the axons. However, in the hypoglossal nerve the antigen was found to accumulate proximal to a ligation of the nerve, suggesting it was made by the neurons and transported down the nerve by axoplasmic flow. This impression was supported by examining neuronal cell bodies in the SCG, dorsal root ganglia and submandibular ganglion, all of which contain readily detectable cytoplasmic Thy-1. In the SCG this cytoplasmic antigen was shown to include the pool of newly synthesized Thy-1. It was increased by treatment of the ganglion with colchicine, and decreased by cycloheximide. Conversely, treatment of hypoglossal nerve trunk with colchicine did not lead to the appearance of the antigen around the non-neuronal perikarya. It is therefore concluded that in those parts of the adult rat P.N.S. examined, Thy-1 is made by neurons and occurs generally on the plasma membrane of axons.

The long term culture of bulk-isolated bovine oligodendroglia from adult brain

Oligodendroglia isolated from adult bovine brain by the method of Farooq et al. could be plated on polylysine-coated plastic dishes with an efficiency of 55-80%, and maintained in culture for as long as 4 months. The addition of cytosine arabinoside to the nutrient medium resulted in cultures that were approximately 90% oligodendroglia and 10% large fibroblasts. From 50 g of white matter 100-160 X 10(6) oligodendroglia, containing approximately 6-10 mg protein, could be obtained in culture. These small round cells started to send out processes at 5 days in vitro and by 2 weeks they formed an extensive network of processes. By immunofluorescence, all cells of this morphology were positive for galactocerebroside (GC) and myelin basic protein (MBP), and negative for glial filament protein and fibronectin. Most of the large flat cells were positive for fibronectin and negative for GC, MBP and glial filament protein. As the cultures aged the oligodendroglia tended to clump and blebs formed on the surface of both perikarya and processes. By 4 months they showed evidence of degeneration and detached from the substrate. Electron microscope examination showed that the cells had the appearance typical of oligodendroglia in situ. The somata were round to elliptical, with eccentrically placed nuclei, and were larger than freshly isolated cells. They grew directly on the substrate or on the surface of the fibroblasts. In older cultures the cells formed tight nests. The somata were enveloped by sheets of oligodendrocyte cytoplasm, sometimes having a myelin-like appearance. Gap junctions and small desmosomes were seen between oligodendroglial processes and between oligodendroglia and fibroblasts. The cytoplasm was characterized by a prominent Golgi apparatus, many mitochondria and lysosomes, scattered rough endoplasmic reticulum, free ribosomes, frequent centrioles and an abundance of microtubules. In cells from older cultures large vacuoles were common, and rarely they had multilamellar walls with alternating major and minor dense lines resembling myelin.

A syringe modification for the simple and rapid dissociation of post-natal rat cerebral tissue for preparing primary cultures of mixed glial cells

Mechanical disruption of 2-day post-natal rat cerebral tissue without enzyme pretreatment through 21-gauge and 23-gauge hypodermic needles on a 1 ml disposable plastic syringe, gives dissociated preparations which contain between 1.7 and 2.1 X 10(7) cells/100 mg wet tissue. At a plating density of between 7.1 and 9.2 X 10(5)/cm2 in culture, between 2 X 10(5) and 2 X 10(6) cells are recovered after 7 days. Use of needles finer than 23-gauge resulted in lower cell yields and loss of galactocerebroside-positive oligodendrocytes. The method described is convenient for the routine preparation of mixed primary glial cultures on a regular basis where many cerebra need to be processed.

Astrocyte cultures from adult rat brain. Derivation, characterization and neurotrophic properties of pure astroglial cells from corpus callosum

It has not as yet been routinely possible to derive primary cultures of glial cells from adult rat brain tissue even when adopting strategies that have proven successful with perinatal tissue. We now report that in response to a surgical lesion and a period of postoperative 'priming' in vivo, proliferating cultures of astroglial cells can be derived from the normally quiescent glia of the corpus callosum region of the adult rat brain. In such cultures the predominance of astroglia and the virtual absence of oligodendroglia and neurons has been established by the use of a variety of cell-type specific antisera. Fibroblasts, the only other cell type identified, when not numerous could be successfully eliminated by treatment of the cultures with anti-Thy-1 antibodies and guinea pig complement. Pure astroglial cells from adult brain have been sub-cultured and maintained for up to 4 months in vitro, providing suitable quantities of cells for studies on the trophic interaction between glia and neurons. In long-term culture the adult astrocytes maintain a flattened undifferentiated morphology but readily assume a stellate shape with long branching processes upon the addition of a crude homogenate from bovine pituitary.

Neural cell markers and their applications to neurology

Cell-type-specific antigenic markers which allow the unambiguous identification of the major neural cell types in dissociated cell cultures of central nervous system (CNS) and peripheral nervous system (PNS) tissues from a variety of animal species have recently been established. The use of many of these markers has also been extended to nervous tissue sections in which the in vivo properties of neural cells can be studied. Markers may be either cell surface or intracellular components of neural cells. Cell surface markers can be used to separate different cell types to produce purified cell populations. The ability of monoclonal antibodies to recognise single antigenic determinants is likely to prove superior to conventional heteroantisera in recognising cell surface antigens. Although the present techniques have intrinsic limitations, nonetheless both surface and intracellular markers should prove to be of great value in a wide range of biological and clinical neurological studies.

Long term culture of bovine oligodendroglia isolated with a Percoll gradient

Oligodendroglia were isolated from calf central nervous system (CNS) white matter by trypsinization in phosphate buffered saline and separation by centrifugation through Percoll. Using antisera to phenotypic markers and double labelling experiments we were able to identify essentially all cells in the cultures. The cells obtained were: (1) viable; (2) had intact plasma membranes and well preserved organelles, ribosomes and mitochondria; and (3) were greater than or equal to 95% oligodendroglia 16-20 h after isolation as determined by ability to bind antigalactocerebroside antibodies (anti-GalC). Oligodendroglia could be cultured for several weeks to months. Oligodendroglia established and maintained processes which bound anti-GalC. Myelin basic protein could be demonstrated in the cytoplasm of 40-60% of oligodendroglia cell bodies but not in the processes.

Oligodendrocytes from postnatal cat brain in cell culture. I. Regeneration and maintenance

Oligodendrocytes isolated in bulk from white matter of cat brain (8-12 weeks of age) employing a Percoll gradient as the final purification step, were cultured and maintained for more than 10 weeks. Different parameters, e.g. coating material and the age of the animals appeared to have some influence on attachment rate and survival of the cells. Oligodendrocytes from older animals, or oligodendrocytes seeded into poly-L-lysine coated culture dishes revealed a marked tendency to form aggregates. Of the dispersed cells, 80-99% can be classified as oligodendrocytes by transmission electron microscopy (TEM) and immunocytochemical markers. Aggregates which were re-seeded consisted of more than 90% oligodendrocytes. About one day after attachment to the supporting layer the cells start to regenerate their processes which sometimes broaden at their ends into shovel-like, membranous extensions.