Co-cultivation of astroglial and neuronal primary cultures from rat brain

A technique is described for a two-cell co-cultivation system which permits in vitro evaluation of neuron-glia interactions. Primary astroglial enriched cultures from newborn rat cerebral hemispheres, striatum or cerebral cortex, grown for 3 days, were co-cultivated with primary neuron-containing cultures from 15- to 17-day rat embryo cerebral hemispheres, substantia nigra or brainstem, respectively, grown for 10 days on polylysine-coated surfaces. The neuronal cells were identified morphologically and immunohistochemically by antibodies to neuron-specific enolase. The two cultures were grown together for 7 days, separated by a U-formed 1 mm glass-rod. The results show that neurons exert a morphogenetic effect on astroglial cells in the form of extension of cell processes. The co-culture system allows investigation of potent local humoral interactions between astroglial cells and neurons.     

Fatty acid and long-chain base composition of gangliosides isolated from adult human brain

A series of major and minor ganglioside species were isolated from a single human adult brain and analyzed for their lipophilic composition. Hematosides, GM3 and GD3, each showing double bands on thin-layer chromatograms, were separated into the upper band and lower band fractions to be analyzed for the heterogeneity of their ceramide moieties. The upper band fractions of GM3 and GD3 were found to contain relatively high amounts of longer-chain fatty acids (C20-C26), whereas the lower band fractions contained high amounts of shorter-chain fatty acids (C16-C18). Compared to other gangliosides which contain hexosamine, the two hematosides contained a smaller proportion of stearic acid. The proportion of 4-eicosasphingenine was found to increase with increasing sialic acid content in gangliosides. These findings suggest that, in the biosynthesis of various gangliosides, N-acetylhexosamine is preferentially transferred to hematosides rich in stearic acid, and sialic acid residues are preferentially transferred to 4-eicosasphingenine-containing species.     

Expression of adrenergic receptors in individual astrocytes and motor neurons isolated from the adult rat brain.

Attempts to show the distribution of adrenergic receptors (ARs) in autoradiographs of a brainstem motor nucleus following elimination of motor neurons yielded the unexpected result of an increase in beta-AR density. This increase was related to the gliosis accompanying the motor neuron degeneration. To determine the cells on which the AR subtypes were located, we dissociated cells from various regions of the adult rat brain and subsequently identified astrocytes by glial fibrillary acidic protein (GFAP) immunofluorescence. Slides containing the astrocytes were prepared for autoradiography using the nonselective beta ligand 125I-iodocyanopindolol (125ICYP) or the alpha 1 ligand 125IBE 2254 (125I-HEAT). The addition of the selective beta 1 blocker betaxolol or the beta 2 blocker ICI 118.551 to the incubation medium to displace 125ICYP binding was used to determine the binding of beta-AR subtypes. The great majority (greater than 88%) of isolated astrocytes sampled from the trigeminal motor nucleus, cerebral cortex, striatum, and cerebellum showed beta-AR binding. Astrocytes from the first three regions had similar average densities of beta-ARs, whereas the density in cerebellar astrocytes was 2- to 3-fold greater. The beta 2-AR subtype was proportionally greater than the beta 1 subtype in each region. Reactive astrocytes isolated from the trigeminal motor nucleus after degeneration of motor neurons showed a beta-AR density nearly 2-fold greater than resting astrocytes from the same region, with the beta 1 subtype showing the greater proportional increase. There was no beta-AR binding on trigeminal motor neurons. Astrocytes also showed a significant level of alpha 1-AR binding. No differences in alpha 1-AR binding were found in normal astrocytes isolated from the different regions, nor was there an increase in reactive astrocytes. In contrast, trigeminal motor neurons had an alpha 1-AR density nearly 10 times greater than astrocytes. In terms of the NE modulation of synaptic responses in motor neurons, the distribution of ARs would permit NE to act indirectly through alpha 1 and beta receptors on astrocytes and directly through alpha 1 receptors on motor neurons.     

De novo production of alpha 2-macroglobulin in cultured astroglia from rat brain.

Previous studies from our laboratory demonstrated that alpha 2-macroglobulin (alpha 2M) is one of the neurite-promoting factors in the conditioned medium of astroglia. In the present study, we further examined the de novo production of alpha 2M in cultured astroglia by determining the expression of alpha 2M mRNA, and the biosynthesis of [35S]methionine-labeled alpha 2M protein. We analyzed the mRNA of cultured astroglia by differential hybridization using specific probes to alpha 2M and its homologous protein, alpha 1-inhibitor 3 (alpha 1I3), after amplification of reverse-transcribed cDNA with the polymerase chain reaction. The result clearly showed that only alpha 2M mRNA is expressed in cultured astroglia. Northern blotting analysis revealed that alpha 2M mRNA is expressed mainly in the astroglia and is not detected in neurons, microglia and meningeal fibroblasts. Furthermore, the biosynthesis of alpha 2M protein in the astroglia was confirmed by an immunoprecipitation experiment after labeling of each type of cell with [35S]methionine. It was concluded that alpha 2M is produced in the cultured astroglia which is the major source of alpha 2M production among various types of cells in rat brain.     

Ganglioside synthesis and transport in regenerating sensory neurons of the rat sciatic nerve

The sciatic nerves of rats were crushed with fine forceps and allowed to survive for 3 or 7 days, at which time the 5th lumbar dorsal root ganglion was injected with [3H]glucosamine. Animals were killed 18 h later and the nerves proximal and distal to the crush site were cut into 3 mm segments. Gangliosides were purified from these segments, and radioactivity was separately measured in gangliosides, neutral glycolipids and glycoproteins. For all 3 fractions, radioactivity was distributed similarly between the crush site and point of maximum axonal elongation. A second smaller peak of ganglioside radioactivity was seen to span a few segments immediately distal to the point of maximum axonal elongation. We propose two possible explanations for this: (1) it represents ganglioside synthesis by Schwann cells (from blood-borne [3H]glucosamine) as part of the mitogenic response of these cells to the reappearance of axons; or (2) recently synthesized, transported gangliosides are released from the growth cone and taken up by adjacent mitogenic Schwann cells.     

Long-term microglial and astroglial activation in the hippocampus of trimethyltin-intoxicated rat: stimulation of NGF and TrkA immunoreactivities in astroglia but not in microglia

In the present study we investigated the microglial and astroglial response after trimethyltin (TMT) exposure over a prolonged period of time. Male Wistar rats were given a single dose of TMT (8 mg/kg, i.p.) and survived 4, 7, 21, 60 and 180 days after the administration of the toxin. Histochemistry (Griffonia simplicifolia lectin staining) and immunocytochemistry for GFAP were applied to identify micro- and astroglial cells, respectively. To assess the trophic response of glial cells (NGF and TrkA expression), single or double staining experiments were performed. In addition, the biochemical evaluation of GFAP and NGF were carried out at chosen timepoints using immunoblotting technique and ELISA, respectively. The main findings of our study were as follows. (1) A protracted activation of microglia (at least up to 2 months posttreatment). (2) A long-lasting expression of GFAP immunoreactivity (at least up to 6 months posttreatment) and a steady increase in GFAP content (at least up to 2 months posttreatment). (3) The appearance of enormously enlarged, round-shape astrocytes exclusively localized to CA1 and observed 2 months posttreatment. (4) The stimulation of NGF and TrkA expression in reactive astrocytes. (5) The strongest activation of micro- and astroglia coincided with the most prominent neurodegeneration in the hippocampus, i.e., in CA4/CA3c and CA1. It is tempting to assume that the activation of glial cells in the hippocampal areas particularly vulnerable to TMT may affect neuronal fate after neurotoxic insult.     

Characterisation of microglia isolated from adult human and rat brain

A method has been developed to isolate microglia from adult human and rat brain cell suspensions by rosette formation via Fc receptors. Immunocytochemical characterisation of the cells immediately following isolation and after 7-10 days in vitro with a panel of monoclonal antibodies has demonstrated that microglia from adult brain have the phenotypic characteristics and phagocytic capacity of mononuclear phagocytes, but lack the hydrolytic enzyme, non-specific esterase. The ability to isolate rapidly a purified population of microglia from adult brain provides a means for investigating mechanisms of activation and differentiation of tissue macrophages, which could elucidate their role in inflammation of the central nervous system.     

Theanine, an ingredient of green tea, inhibits [3H]glutamine transport in neurons and astroglia in rat brain

We have previously shown that theanine (=gamma-glutamylethylamide), an ingredient of green tea, has a protective effect against ischemic neuronal death in the hippocampal CA1 region of the gerbil brain without affecting ligand binding to ionotropic receptor subtypes of the neurotransmitter glutamate structurally related to theanine. The neurotransmitter pool of glutamate is thought to be fueled by the entry of the other structural analog glutamine (Gln) and subsequent cleavage by glutaminase. Although theanine did not inhibit [3H]glutamate accumulation, [3H]theanine was actively accumulated in a temperature-dependent and saturable manner in rat brain synaptosomal fractions. The accumulation of [3H]theanine was markedly inhibited by Gln in a concentration-dependent manner, whereas [3H]Gln accumulation was inhibited by theanine vice versa. Both [3H]theanine and [3H]Gln accumulations were decreased after the replacement of sodium chloride with choline chloride, along with similarly high distribution profiles in telencephalic structures. A similar equilibrium was observed within 30 min at 30 degrees C for the accumulations of both [3H]theanine and [3H]Gln in cultured rat neocortical astroglia as well as neurons, whereas theanine inhibited [3H]Gln accumulation in a concentration-dependent manner at 0.1-10 mM. Furthermore, sustained exposure to 10 mM theanine led to a significant decrease in the level of extracellular glutamate released from cultured neurons. These results suggest that the green tea ingredient theanine would be an inhibitor of different transporters capable of transporting Gln across plasma membranes toward the modulation of the glutamate/Gln cycle required for the neurotransmitter pool of glutamate in neurons.     

Rat brain microvessel extracellular matrix modulates the phenotype of cultured rat type 1 astroglia

Astroglia from immature rat cerebral white matter which were plated on the insoluble extracellular matrix (ECM) secreted by rat cerebral microvessel endothelial cells (RCMEC) and maintained in a defined medium were induced to become stellate and to express glutamine synthetase. These effects were not elicited by RCMEC-conditioned medium. ECM secreted by rat pleural mesothelium elicited a lesser proportion of stellate astroglia and did not induce glutamine synthetase.     

The presence of glutathione in primary neuronal and astroglial cultures from rat cerebral cortex and brain stem

Summary The concentration of the tripeptide glutathione (GSH) was measured in primary cultures of neurons and astroglial cells from rat cerebral cortex and brain stem. The concentration of GSH was found to be approximately 20 nmol/ mg protein in the neuronal culture from the cerebral cortex and ca. 40 nmol/ mg protein in the neuronal brain stem cultures. A GSH concentration of approximately 20 nmol/mg was observed in the astrocyte cultures from both brain regions. The possibility to increase the GSH concentration was tested by incubating the cultures in the presence of the GSH precursor -glutamylcysteine (-GC). In the cultured astrocytes -GC produced a dose-dependent increase in GSH. A similar increase was observed in the neuronal cultures, but this effect failed to reach statistical significance.     

Region distribution of the gangliosides in rat brain after chronic ethanol treatment

In this study the effects of chronic ethanol administration on the regional distribution of brain gangliosides were investigated. A total of 36 60-d-old male Wistar rats weighing approximately 200 g was divided into two groups of 18 animals each. The ethanol-consuming group was offered drinking fluid (25% sucrose-32% ethyl alcohol, w/w) ad libitum, and the control group was given a sucrose solution isocaloric with the ethanol-sucrose solution. After 6 mo of chronic ethanol treatment, cerebral cortex, N. caudatus, hypothalamus, thalamus, and hippocampus were analyzed with respect to their ganglioside pattern (G_M2, G_M1, G_D1a, G_D1b, G_T1b, and G_Q). The results showed that there were highly significant effects of ethanol on hypothalamus G_D1b and G_T1b, thalamus G_M1 and G_D1a, and hippocampus G_M1, G_D1b, and G_T1b ganglioside distribution. It was found that ethanol differently affected the gangliosides in these brain regions.     

Morphological modulation of cultured rat brain astroglial cells: antagonism by ganglioside GM1

Secondary cultures of neonatal rat astroglial cells, maintained in a serum-free, chemically defined medium were treated with several agents thought to activate cyclic AMP-synthesizing systems. Dibutyryl cyclic AMP (dBcAMP), forskolin and cholera toxin promoted, within 2 h, the near-complete conversion of 1-day-old (D1) astroglial cells from a flat, epithelioid morphology to a stellate (star-shaped) morphology. With all 3 agents, cell susceptibility to morphological change declined with culture age, 5-day-old cultures failing to respond altogether. D1 cultures, after 48 h of treatment, had reverted to the flat morphology. Gangliosides reported to stimulate adenylate cyclase were also tested, using purified GM1 X GM1 failed to stimulate the conversion to stellate morphologies. GM1, however, did affect these astroglial cells by causing a block or reversal of their morphological response to dBcAMP, forskolin or cholera toxin. The GM1 response was specific for the intact ganglioside molecule, asialo GM1 and sialic acid having no effect. Gangliosides GD1a, GD1b and GT1b were also active, being effective at ca. 4-fold lower concentrations. The response to GM1 appeared to involve a direct interaction with the astroglial cell, rather than influencing either substratum or medium components.     

Influence of GM1 gangliosides on the growth of cultured rat embryonic serotonergic neurons

GM1 gangliosides were added to the medium of cultured raphe neurons enriched in the serotonergic phenotype in order to study their influence on biochemical and morphological growth parameters of serotonergic neurons. After 2 days of culture in the presence of GM1, specific uptake of serotonin measured by scintillation counting exhibited a moderate but significant increase for a GM1 concentration of 5 × 10⁻⁸M. Morphological parameters of 5-HT neurons were measured after immunocytochemical staining with specific serotonin antiserum and digitalization of immunoreactive cells. Eight parameters were studied; for concentrations of 5 × 10⁻⁸ and 10⁻⁷M of GM1, the absolute neuritic field area and the total length of the segments were significantly increased, whereas the number of neuritic segments and their mean length were not modified. We conclude that GM1 ganglioside has a significant influence on the growth of serotonergic neurons. Moreover, electron microscopy showed, on treated cultures, a dramatic increase of the number of spicules all along the neuron's process, suggesting that GM1 could act by modifying the attachment of cells to their substrate. The possible molecular mechanisms of the action of GM1 are discussed.     

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 succesfully eliminated by treatment of the cultures with anti-Thy-1 antibodies and guinea pig compliment. 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 undiffirentiated morphology but readily assume a stellate shape with long branching processes upon the addition of a crude homogenate from bovine pituitary.     

The output of neuronotrophic and neurite-promoting agents from rat brain astroglial cells: a microculture method for screening potential regulatory molecules

Throughout embryonic development, as well as in response to injury of the central nervous system, astroglial cells may present neurons with a critical supply of neuronotrophic and neurite-promoting factors which control, respectively, neuronal survival and axonal growth. The identification of such astroglial cell-derived factors, as well as of specific extrinsic agents regulating their production, will require the use of in vitro techniques. We define here a new microculture system in which added agents can be screened for their ability to enhance or inhibit the output of trophic and neurite-promoting factors from purified neonatal rat brain astroglial cells. With such a procedure, thousands of replicate secondary astroglial cultures can be set-up and maintained in chemically defined medium, on a defined substratum and in a viable, low proliferative stable state. These cultured astroglial cells release into their medium at least three distinct and separable types of agents addressing nerve cells in vitro: (i) high molecular weight trophic factors (Mr greater than 10,000) which support the survival of embryonic peripheral neurons; (ii) low molecular weight trophic agents (Mr less than 10,000) supporting embryonic central neurons; and (iii) polyornithine-binding neurite-promoting factors which enhance neuritic regeneration for both peripheral and central neurons. The temporal release patterns of these three agents from astroglial cultures are quite distinct suggesting that their output is independently regulated.     

Primary cultures from defined brain areas; effects of seeding time on cell growth, astroglial content and protein synthesis

The influence of seeding time on cell growth, astroglial content and on protein synthesis during cultivation was determined in primary cultures from 3 phylogenetically different brain areas from rat cerebral cortex, striatum and brainstem. Brainstem cultivated from 17-day-old embryos and all the cultures studied from the 3 brain areas of newborn and 7-day-old rat showed a similar increase in total and water-soluble protein during cultivation. Glial fibrillary acidic protein (GFAp, alpha-albumin) levels increased with age in all cultures studied. There was a rapid increase in GFAp (alpha-albumin) between 1 and 2 weeks in cultures from newborn and between 2 and 3 weeks in brainstem cultures from 17-day-old embryos, these increases being slower thereafter. Incorporation of [3H]valine into soluble protein was lower in 3-week-old cultures than in 1- and 2-week-old cultures derived from newborn and 7-day-old rat brain. The incorporation rates were similar in comparisons of the various cultures. Similar results were obtained from embryonic cultures, although the decrease in incorporation rate was between 3 and 4 weeks. The efficiency of incorporation (% TCA-precipitated material/total [3H]activity) was higher in 2- and 3-week-old than in 1-week-old cultures from newborn and 7-day-old rats and in 3- and 4-week-old cultures of brainstem from 17-day-old rat embryos. These findings suggest a cell differentiation during cultivation. The results show that seeding time has a variable influence on cultures from the different brain areas studied concerning cell growth, astroglial content and probably differentiation during cultivation. Embryonic cell cultures seem, in general, to develop one week later than neonatal and postnatal ones. Cultures of newborn rat cells from cerebral cortex, striatum and brainstem show many similarities in the above parameters during cultivation. This is also the case for brainstem cultures from embryonic rat.