Cellular resistance to Evans blue toxicity involves an up-regulation of a phosphate transporter implicated in vesicular glutamate storage.

It has recently been suggested that the brain-specific Na+-dependent phosphate inorganic co-transporter (BNPI) is able to support glutamate transport and storage in synaptic vesicles. A procedure for measuring the vesicular pool of glutamate is described and was used to select cell lines according to their glutamate storage capacity. Two cell lines were selected: C6BU-1, with a large intracellular glutamate storage capacity, and NG108-15, devoid of it. Their contents in BNPI mRNA were compared by RT-PCR. We found that both cell lines had BNPI, but in addition C6BU-1 alone expresses the other isoform, DNPI. We also carried out a clonal selection of NG108-15 cells in the presence of the dye Evans blue, a competitive inhibitor of vesicular glutamate transport, very toxic for cells in culture. It was assumed that only those that sequester and eliminate the drug by overexpressing a vesicular glutamate transporter would survive. We found that the NG108-15 clones resistant to Evans blue had an increased storage capacity for glutamate. These cells also up-regulated the BNPI isoform of the phosphate transporter as shown by RT-PCR and northern blot.

Background osmolyte current involved in cell volume regulation of neuroblastoma x glioma hybrid NG108-15 cells.

Recently, we showed that at constant extracellular osmolarity, the volume of NG108-15 cells was dependent on the external NaCl concentration and we assumed that the responsible mechanism was mediated by background channels (Rouzaire-Dubois et al. 1999). In order to confirm this view, the mean cell volume and the background current of NG108-15 cells were measured under different experimental conditions, after blockade of specific volume regulating mechanisms and ion channels. When the external NaCl concentration was decreased, the reversal potential of the background current was shifted toward negative values and the membrane conductance decreased. Opposite effects were observed when the NaCl concentration was increased. Substitution of external Na+ with various monovalent cations altered the mean cell volume by: Rb+, +17%; Cs+, +15%; K+, +10%; Li+, -6%; choline, -9%; N-methylglucamine, -25% . The reversal potential of the background current and the membrane conductance were altered by these Na+ substitutes in such a way that the cell volume increased linearly with the background current at -60 mV. Substitution of external Cl- with various monovalent anions altered the mean cell volume by: I-, +4%; Br-, 0%; NO-, -3%; F-, -5%; isethionate, -30%; gluconate, -50%. Cl- substitutes did not significantly alter the background current at -60 mV, except F- which increased it by 39%. These results suggest that 1. the cell volume is dependent on ion fluxes through background channels; 2. electrogenic cation fluxes are larger than anionic ones and the background current is proportional to the difference between these fluxes; 3. whereas external cations do not interfere with anion fluxes, external anions alter cation fluxes.

Control of cell proliferation by cell volume alterations in rat C6 glioma cells.

K+ and Cl- channels are involved in regulating the proliferation of a number of cell types. Two main hypotheses have been proposed to explain the mechanism by which these channels influence cell proliferation: regulation of membrane potential and regulation of cell volume. In order to test these hypotheses, we measured, under different experimental conditions, the volume, membrane potential and rate of proliferation of C6 glioma cells. Cells cultured in control medium for 1-4 days were compared with cells cultured for the same period of time in the presence of broad spectrum channel blockers: tetraethylammonium, 5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB) and Cs+, in hypertonic media (29% increased osmolarity with NaCl, KCl or sucrose), in hypotonic medium (23% decreased osmolarity with H2O) or in the presence of the specific channel blockers, i.e. mast cell degranulating peptide, charybdotoxin or chlorotoxin. In all of these conditions, we observed a close correspondence between the rate of proliferation and the mean cell volume. The proliferation decreased when volume increased. Moreover, whereas control cells were flattened, spindle-shaped, bipolar or multipolar, cells cultured in media supplemented with NPPB, KCl or CsCl were round with few processes. Of the agents tested, only KCl and Cs+ depolarized the cells. These results show that alterations of the rate of proliferation by K+ and Cl- channel blockers or anisotonia are closely related with changes in cell volume or form but are not correlated with changes in membrane potential.

Evidence for several mechanisms of volume regulation in neuroblastoma x glioma hybrid NG108-15 cells.

Volumes of neuroblastoma x glioma hybrid NG 108-15 cells were electronically measured in order to characterize the mechanisms involved in volume regulation in isosmotic and anisosmotic conditions. The cells behave as perfect osmometers when tonicity was changed at constant chloride concentration by adding sucrose or replacing NaCl with CaCl2 or MgCl2. In contrast, the cell volume was poorly dependent on tonicity when the Cl- concentration was changed by adding NaCl or H2O. Cell shrinkage was induced by cell stirring or after a hypotonicity-induced swelling. These volume decreases were abolished by caffeine but not by ryanodine or EGTA. Shrinkage was also induced by the Ca2+ ionophore ionomycin. The ionomycin-induced volume decrease was abolished by EGTA. Cell swelling induced an outwardly rectifying Cl- current which was blocked by 5-nitro-2-(3-phenylpropylamino)benzoic acid, 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid and dihydroindenyloxy-alkanoic acid. When the tonicity was reduced at constant Cl- concentration by replacing NaCl with CaCl2 or MgCl2, the volume increased and then slowly decreased towards its control value. This regulatory volume decrease was blocked by 5-nitro-2-(3-phenylpropylamino)benzoic acid, 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid and dihydroindenyl-oxy-alkanoic acid. Long-term (hours-days) cell shrinkage was induced by a reduction of the culture medium osmolarity. Long-term cell swelling was induced by an increase of the culture medium osmolarity. These volume changes were abolished by the protein translation inhibitor cycloheximide. The results suggest that NG 108-15 cell volume is regulated by at least four interacting mechanisms controlled, respectively, by intracellular Ca2+, extracellular NaCl, cell volume and intracellular ionic strength. The speculative nature of ionic systems responsible for these volume regulating mechanisms is discussed.