Microgravity-induced alterations in cultured testicular cells

Cultured STe cells (2n karyotype) from swine testis were submitted to simulated microgravity using a 3D Random Positioning Machine for 5 min., 15 min., 30 min., 1 h and 23 h. Sample processing included: histological characterization of cell types, immunohistochemical identification of (i) microtubules (a-tubulin), (ii) alkaline phosphates, (iii) 3 beta-hydroxy-steroid-dehydrogenase (3?-HSDH), and histochemical lipid analyses. After 5 min. simulated microgravity a slight microtubule disorganisation occurred, which increased dramatically with increasing microgravity duration. After 23 h microtubule arrays were completely disrupted. 3 beta-HSDH immunostaining was detectable only in one cell type: under control conditions and 5 min. into microgravity immunoreactivity was strong, but completely disappeared thereafter. Immunostaining intensity for alkaline phosphates, a good marker for myoid cells, decreased after 15 min. in microgravity.     

GABA metabolism in cultured glial cells

GABA-transaminase has been characterized in cultured astrocytes. It is identical to the synaptosomal and perikaryal enzyme in terms of charge, molecular weight, and stability, but it differs in its affinity for GABA, which is much higher in the glial compartment. GABA-transaminase has been shown to be inducible by high GABA concentrations, which suggests that astrocytes have the possibility not only to transport GABA but also to metabolize the amino acid which is taken up.     

Production of GABA by cultured hippocampal glial cells

Medium conditioned by cultured hippocampal glial contains an inhibitory factor that can hyperpolarize and suppress neuronal activity. Using biochemistry, electrophysiology, pharmacology, and mass spectrometry, we have identified the inhibitory factor as GABA (gamma-aminobutyric acid). Like GABA, the inhibitory factor increases chloride and potassium currents in neurons, which can be blocked by bicuculline. Mass spectrometry analysis of conditioned medium reveals peaks that are identical to that for GABA. Up to 500 micromolar GABA is found in conditioned medium from glial cultures. No GABA is found in conditioned medium from neuronal cultures. Hippocampal glia make much more GABA than cortical glia or glia from other brain regions. It is not clear how hippocampal glia synthesize GABA. Although they express GAD mRNA and adding glutamate to the culture medium increases the amount of GABA produced, other data suggest that glia do not use GAD to make GABA. Identifying the mechanism(s) by which GABA is produced by hippocampal glia would help clarify its role in modulating neuronal activity in the brain.     

Phenotypic changes in satellite glial cells in cultured trigeminal ganglia

Satellite glial cells (SGCs) are specialized cells that form a tight sheath around neurons in sensory ganglia. In recent years, there is increasing interest in SGCs and they have been studied in both intact ganglia and in tissue culture. Here we studied phenotypic changes in SGCs in cultured trigeminal ganglia from adult mice, containing both neurons and SGCs, using phase optics, immunohistochemistry and time-lapse photography. Cultures were followed for up to 14 days. After isolation virtually every sensory neuron is ensheathed by SGCs, as in the intact ganglia. After one day in culture, SGCs begin to migrate away from their parent neurons, but in most cases the neurons still retain an intact glial cover. At later times in culture, there is a massive migration of SGCs away from the neurons and they undergo clear morphological changes, and at 7 days they become spindle-shaped. At one day in culture SGCs express the glial marker glutamine synthetase, and also the purinergic receptor P2X7. From day 2 in culture the glutamine synthetase expression is greatly diminished, whereas that of P2X7 is largely unchanged. We conclude that SGCs retain most of their characteristics for about 24?h after culturing, but undergo major phenotypic changes at later times.     

Cysteine sulfinic acid uptake in cultured neuronal and glial cells

The presence of an efficient high affinity uptake system for L-CSA has been demonstrated in cultured neuronal and glial cells of various types. In neurons and most glial cells L-CSA uptake is inhibited by acidic amino acids,L-glutamate andL-aspartate and requires sodium ions; however the sodium dependence varies from one cell type to the other. The characteristics of the uptake system change during cell maturation, especially in astroblasts. The predominance of CSA uptake in glial cells as compared to neurons, the similarity of the kinetic parameters and of the structural specficity ofL-glutamate uptake suggest that both excitatory amino acids are transported by a common system. In view of accumulating evidence, the present results are in agreement with a role of CSA as a neurotransmitter and as a precursor for taurine biosynthesis in the central nervous system.     

Arachidonic acid inhibits glycine transport in cultured glial cells.

The effects of arachidonic acid on glycine uptake, exchange and efflux in C6 glioma cells were investigated. Arachidonic acid produced a dose-dependent inhibition of high-affinity glycine uptake. This effect was not due to a simple detergent-like action on membranes, as the inhibition of glycine transport was most pronounced with cis-unsaturated long-chain fatty acids, whereas saturated and trans-unsaturated fatty acids had relatively little or no effect. Endogenous unsaturated non-esterified fatty acids may exert a similar inhibitory effect on the transport of glycine. The mechanism for this inhibitory effect has been examined in a plasma membrane vesicle preparation derived from C6 cells, which avoids metabolic or compartmentation interferences. The results suggest that part of the selective inhibition of glycine transport by arachidonic acid could be due to the effects of the arachidonic acid on the lipid domain surrounding the carrier.     

Amino acid current through anion channels in cultured human glial cells

During volume regulation in hypotonic media, glial cells release a large portion of their amino acids. These amino acid losses appear to be mediated by a diffusion type of transport and a swelling-activated chloride channel seems to be involved. The objective of this project was to provide direct evidence that amino acids could diffuse through a Cl^? channel. Using a human glial cell line, Cl^? currents activated in hypotonic media were measured in whole-cell patch clamp. To measure the currents produced by amino acids, it was necessary to increase the pH of external solutions to basic values reaching 9.6 and 10.0 to raise the concentration of the anionic form of these amino acids. Introducing external hypotonic media containing high concentrations of amino acids, like glycine, taurine, glutamine and glutamate, it was possible to measure their respective current-voltage curves with NMDG-Cl-filled pipettes. From the reversal potentials, their permeability ratios with respect to chloride were determined. It was found that the low molecular weight amino acids, like glycine, were most permeant, while the larger ones, like glutamine, had a lower permeability with respect to chloride. The amino acids with two carboxyl groups, like glutamate, had a much lower permeability ratio. The reversal potentials for some metabolites, like lactate and malate were also measured for comparison. These results demonstrate that amino acids can diffuse through anion channels and that activation of these channels in pathological conditions could be at least partly responsible for the observed increase in external amino acids.     

Adenosine transport by cultured glial cells from chick embryo brain

The transport of adenosine was studied in pure cultures of glial cells from chick embryo brain. In order to avoid complications in uptake measurements due to adenosine metabolism, cultures were depleted of ATP by incubation with cyanide and iodoacetate prior to addition of [³H]adenosine. Under the 5- to 25-s periods used for the transport assay, no adenosine metabolism could be detected. Initial rates of adenosine transport under these conditions obeyed the Michaelis-Menten relationship with K_m = 370 μM and V_max = 10.3 nmol/min/mg cell protein. ATP depletion or elimination of Na⁺ from the assay medium had no significant effect on initial rates of adenosine uptake. However, when assays were carried out under conditions of significant adenosine metabolism (10-min uptake in the absence of metabolic inhibitors), a high-affinity incorporation process could be demonstrated in the glial cells (K_m = 12 μM; V_max = 0.34 nmol/ min/mg protein). The transport activity expressed in ATP-depleted glial cells was most sensitive to inhibition by nitrobenzylthioinosine, dipyridamole, and N⁶-benzyladenosine. In decreasing order of potency, N⁶-methyladenosine, 2-chloroadenosine, inosine, and thymidine also blocked adenosine translocation in glial cultures. Thus, adenosine transport by cultured glial cells occurs by means of a low-affinity, facilitated diffusion system which is similar to the nucleoside transporter in cells of nonneural origin.     

Synthesis and release of sulfated glycoproteins by cultured glial cells

Both primary cultured glial cells and cloned (C-6) glioma cells have been shown to synthesize and release sulfated glycoproteins. It was found that N-linked tri- and tetra-antennary glycopeptides recovered from the glycoproteins contained most of the (35S) sulfate label. C-6 glial cells showed a higher rate of oligosaccharide sulfation than the primary glial cultures. Both cell types exhibited a high rate of release of sulfated glycoproteins into the medium. The ratio of 35S/3H incorporated from (35S) sulfate and (3H) glucosamine in the released material was higher than that of the glycoproteins associated with the cell, indicating an enrichment of sulfated glycoproteins in the secreted materials. Monensin inhibited both the synthesis and the release of sulfated glycoproteins.     

Voltage-gated calcium channel types in cultured C. elegans CEPsh glial cells

The four cephalic sensilla sheath (CEPsh) glial cells are important for development of the nervous system of Caenorhabditis elegans. Whether these invertebrate glia can generate intracellular Ca²⁺ increases, a hallmark of mammalian glial cell excitability, is not known. To address this issue, we developed a transgenic worm with the specific co-expression of genetically encoded red fluorescent protein and green Ca²⁺ sensor in CEPsh glial cells. This allowed us to identify CEPsh cells in culture and monitor their Ca²⁺ dynamics. We show that CEPsh glial cells, in response to depolarization, generate various intracellular Ca²⁺ increases mediated by voltage-gated Ca²⁺ channels (VGCCs). Using a pharmacological approach, we find that the L-type is the preponderant VGCC type mediating Ca²⁺ dynamics. Additionally, using a genetic approach we demonstrate that mutations in three known VGCC α₁-subunit genes, cca-1, egl-19 and unc-2, can affect Ca²⁺ dynamics of CEPsh glial cells. We suggest that VGCC-mediated Ca²⁺ dynamics in the CEPsh glial cells are complex and display heterogeneity. These findings will aid understanding of how CEPsh glial cells contribute to the operation of the C. elegans nervous system.     

Characteristics and adaptive regulation of glycine transport in cultured glial cells.

The transport of glycine in C6 glioma cells takes place mainly in a heterogeneous Na+-dependent manner which can be resolved into different components. A Na+- and Cl(-)-dependent component with high affinity for glycine is pH-sensitive and inhibited by sarcosine, all these characteristics corresponding to System Gly. The low-affinity component of the transport of glycine can be discriminated as two components, namely System A and System ASC. The main proportion of glycine transport through the low-affinity system is carried out by the ASC System, which appears to be constitutively expressed by the cells. The adaptive response of the low-affinity Na+-dependent transport of glycine to amino acid deprivation was identified with System A on the basis of its ion-dependency, pH-sensitivity and by inhibition analysis. The possible physiological role of the high- and low-affinity components of the transport system for glycine in glial cells is discussed.     

Density-dependent regulation of cell surface gamma-glutamyl transpeptidase in cultured glial cells.

A decline in cell surface gamma-glutamyl transpeptidase specific activity was previously observed to be concomitant with C6 glial cell proliferation. To elucidate the underlying factor(s) mediating gamma-glutamyl transpeptidase down-regulation, the effects of C6 cell density and culture conditions on cell surface transpeptidase activity levels were investigated. After 24 h of culture, the transpeptidase specific activities were inversely related to the initial plating densities. The lower-density cultures showed an induction within 24 h of plating. As the cultures proliferated, the specific transpeptidase activities declined to a common low level at post-confluency. The gamma-glutamyl transpeptidase down-regulation was unrelated to cell growth rate and was most pronounced during logarithmic proliferation. Induction and down-regulation of gamma-glutamyl transpeptidase activity at low cell densities were not a result of trypsinization. Supplementation of low-density cultures with conditioned medium, use of matrix-coated wells, or periodic replacement of growth media to prevent conditioning had minor effects on the decline of cell surface activity. Kinetic analysis showed that the Michaelis constants and the reaction mechanism were unaltered by cell density, indicating that down-regulation was not due to allosteric factors or an alteration in enzyme character. A reduction in the maximal velocity of cell surface transpeptidation at higher cell densities suggested that gamma-glutamyl transpeptidase down-regulation is related to the concentration of enzyme at the cell surface. Immunocytochemical localization of gamma-glutamyl transpeptidase demonstrated that gamma-glutamyl transpeptidase antigen levels decrease as C6 cell density increases. These results led us to propose that cell-cell contact stimulates the disappearance of gamma-glutamyl transpeptidase from the surface of cultured C6 glial cells.     

Beta blockade induces apoptosis in cultured capillary endothelial cells

Continuous beta blockade stimulates deposition of collagen in the pulmonary alveolar interstitium of adult rats. It also causes changes to the capillary endothelial cell compartment reminiscent of programmed cell death. To test whether beta blockade results in endothelial cell apoptosis, cultures of capillary endothelial cells were treated with both a wide-spectrum beta blocker and a beta-2-specific antagonist. Apoptosis was measured in these cultures using both terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick end labeling and annexin-V assays. Both forms of beta blockade stimulated programmed cell death in these cultures. To test whether the apoptotic effect of beta blockade was related to interstitial collagen deposition, capillary endothelial cells were cocultured with beta-blocked pulmonary fibroblast monolayers. Cocultured endothelial cells were substantially protected from apoptosis after beta blockade; coculture over plain tissue culture plastic or over exogenous collagen films had no effect on programmed cell death in endothelial cells. These results suggest that both pulmonary endothelial and interstitial cells are vulnerable to injury from beta blockade but that paracrine interactions between these cells may protect the peripheral lung from substantive damage.     

Microgravity-induced programmed cell death in astrocytes

Cultured astrocytes were submitted to simulated microgravity using a Fokker clinostat under continuous rotation (60 rpm) for 15', 30', 1h, 20h and 32h. Samples processing included (i) nuclear stainings using Propidium Iodide and 4,6-diamidino-2-phenilindole, dihydro chloride, (ii) immunohistochemical identification of Caspase-7, (iii) identification of DNA fragmentation using the terminal dUTP nick end labelling and (iv) Scanning Electron Microscope analysis. After 30' at simulated microgravity the glial cells showed morphological evidence of apoptosis: cell shrinkage, chromatin condensation, nuclear blebs and fragmentation. The enzyme caspase-7 was present and DNA fragmentation was evident. After 32h the density of the cell population was much lower than that observed in controls.     

Localization of two neurotropic molecules in cultured glial cells by ion microscopy]

The intracellular localization of two families of neurotropic drugs: flunitrazepam and flurazepam (benzodiazepine), triflupromazine and trifluoperazine (phenothiazine) has been studied by ion microscopy. The molecules have been incubated with C6 glioblastoma cells from rat origin and with astroglial primary cultures. The images of the intracellular distributions of the two drugs are easily obtained by selecting the fluorine atom of the molecules. The images obtained show that flunitrazepam and flurazepam, two drugs of the benzodiazepine group are mainly located to the nuclei, whereas triflupromazine and trifluoperazine, two phenothiazines are exclusively located inside the cytoplasm.     

Development of oligodendrocytes. Studies of rat glial cells cultured in chemically-defined medium

Oligodendrocytes are macroglial cells that synthesize and maintain myelin in the central nervous system. Oligodendrocytes in rodent brain are formed postnatally from glial progenitor cells. These progenitors cells are bipotential and differentiate in a later stage of development into type-2 astrocytes. Recent studies with cultured cells indicate that growth factors such as platelet-derived growth factor and ciliary neurotrophic factor are instrumental in the control of these events. This paper discusses various methods for the isolation of oligodendrocytes and for their maintenance in culture. We use cerebra or spinal cords from one-week old rat pups to prepare glial cultures that are enriched in oligodendrocytes (60-80% or greater than or equal to 90%, respectively). After one day in serum-containing medium the cells are kept in chemically-defined medium, supplemented with the hormones insulin, T3 and hydrocortisone. The activities of astrocyte-and oligodendrocyte-specific marker enzymes were measured to evaluate the influence of these hormones on the differentiation of the oligodendrocytes. Finally, glial energy metabolism and the utilization of ketone bodies and of fatty acids are discussed briefly.     

Cell-specific fatty acylation of proteins in cultured cells of neuronal and glial origin

Distinct sets of cellular proteins were labeled with [³H]myristic and [³H]palmitic acids in primary (rat neurons and astroglia) and continuous (murine N1E-115 neuroblastoma and rat C6 glioma) cell cultures derived from the nervous system. Both soluble and membrane proteins were modified by myristate in a hydroxylamine-stable (amide) linkage, while palmitoylated proteins were esterlinked and almost exclusively membrane bound. Chain elongation of both labeled fatty acids prior to acylation was observed, but no protein amide-liked [³H]myristate originating from [³H]palmitate was detected. Fatty acylation profiles differed considerably among most of the cell lines, except for rat astroglial and glioma cells in which myristoylated proteins appeared to be almost identical based on SDS gel electrophoresis. An unidentified 47 kDa myristoylated protein was labeled to a significantly greater extent in astroglial than in glioma cells; the expression of this protein could be related to transformation or development in cells of glial origin.