Charles Levinson scite author profile

Journal Cellular Physiology

1978

The effects of phloretin, H2DIDS (4,4'-diisothiocyano-1,2-diphenylethane-2,2'-disulfonate) and SO4-2 on anion transport in Ehrlich ascites tumor cells was studied in an effort to determine whether Cl- and SO4-2 share a common transport mechanism. Sulfate, in the presence of constant extracellular Cl- (100 mM), reduces Cl- self-exchange by 43% (40 mM SO4-2) and Cl--SO4-2 exchange by 36% (25 mM Cl-/O SO4-2 compared to 25 mM Cl-/50 mM SO4-2). Phloretin blocks without delay and to the same extent the self-exchange of both Cl- and SO4-2. For example, at 10(-4) M phloretin, anion transport is inhibited 28% which increases to 78% at 5 X 10(-4) M. Reversibly bound H2DIDS also inhibits the self-exchange of both Cl- and SO4-2. However, at all H2DIDS concentrations tested (0.5 - 10 X 10(-5) M) SO4-2 transport was far more susceptible to inhibition than that of Cl-. H2DIDS when irreversibly bound to the cell inhibits SO4-2 but not Cl- transport. The results of these experiments are consistent with the postulation that both Cl- and SO4-2 are transported by a common mechanism possessing two reactive sites.

H+ transport and the regulation of intracellular pH in ehrlich ascites tumor cells

Bowen

1984

J. Membrain Biol.

The intracellular pH (pHi) of Ehrlich ascites tumor cells, both in the steady state and under conditions of acid loading or recovery from acid loading, was investigated by measuring the transmembrane flux of H+ equivalents and correlating this with changes in the distribution ratio of dimethyloxazolidine-2,4-dione (DMO). The pHi of cells placed in an acidic medium (pHo below 7.15) decreases and reaches a steady-state value that is more alkaline than the outside. For example when pHo is acutely reduced to 5.5, pHi falls exponentially from 7.20 +/- 0.06 to 6.29 +/- 0.04 with a halftime of 5.92 +/- 1.37 min, suggesting a rapid influx of H+. The unidirectional influx of H+ exhibits saturation kinetics with respect to extracellular [H+]; the maximal flux is 15.8 +/- 0.05 mmol/(kg dry wt X min) and Km is 0.74 +/- 0.09 X 10(-6) M. Steady-state cells with pHi above 6.8 continuously extrude H+ by a process that is not dependent on ATP but is inhibited by anaerobiosis. Acid-loaded cells (pHi 6.3) when returned to pHo 7.3 medium respond by transporting H+, resulting in a rapid rise in pHi. The halftime for this process is 1.09 +/- 0.22 min. The H+ efflux measured under similar conditions increases as the intracellular acid load increases. An ATP-independent as well as an ATP-dependent efflux contributes to the restoration of pHi to its steady-state value.

The transport of chloride in ehrlich ascites tumor cells

Journal Cellular Physiology

Villereal

1976

The steady state transport and distribution of chloride between the intracellular and extracellular phases was investigated when the extracellular chloride concentration was varied by isosmotic replacement with nitrate, bromide and acetate. The results of these experiments show that chloride transport, measured by uptake of 36Cl, is sensitive to the replacement anion. In the presence of nitrate, chloride transport is a linear function of the extracellular chloride concentration. The relationship between chloride transport and extracellular chloride in the presence of bromide is concave upward which suggests that this anion inhibits chloride movement. However, when acetate replaces chloride, the relationship between chloride transport and extracellular chloride is concave downward. The chloride distribution ratio of cells incubated in 145-155mM chloride medium is 0.386 and is not effected by the replacement of chloride with nitrate, bromide or acetate. These findings are consistent with the assertion that chloride transport is composed of two parallel pathways, a diffusional plus a saturating, mediated component. Of the total chloride flux (9.1 mmoles Cl-/kg dry weight per minute) measured in chloride medium (145-155 mM Cl-), the mediated component represents 40% and the diffusional component 60%.

Effect of Valinomycin on Net Sodium and Potassium Transport in Ehrlich Ascites Tumour Cells

1967

Nature

Phosphate concentration and transport in Ehrlich ascites tumor cells: Effect of sodium

Bowen

Journal Cellular Physiology

1982

The effects of extracellular Pi and Na+ on cellular Pi concentration and transport were studied. Steady-state Pi exchange flux was measured by 32P uptake in the presence and absence of Na+. Model experiments were also conducted to assess the possibility that hydrolysis of organic phosphate esters contributes to the chemically measured intracellular Pi concentration of Ehrlich ascites tumor cells. The results of these experiments indicate that hydrolysis of labile organic phosphate esters does not contribute to the measured intracellular pool of Pi. The Pi transport system exhibits an apparent Ks of 0.115 mM Pi and a maximal flux of 1.73 mmole min-1 (kg dry wt)-1. When incubated in a phosphate-buffered choline chloride medium (5 mM Pi) the intracellular Pi and the Pi influx fall by 65 and 88%, respectively. At 5 mM extracellular Pi, the Na+-dependent component of Pi transport fits Michaelis-Menten kinetics with the maximal flux equal to 2.46 mmole min-1 (kg dry wt)-1 and an apparent Ks of 35.4 mM Na+. In addition, a Na+-independent component of Pi transport, comprising about 12% of the total Pi flux, was identified. The data support the hypothesis that a Pi transport system, dependent on Na+, plays a principal role in the maintenance of intracellular Pi concentration.