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Abstract

Objective

To study the mechanism(s) of potassium transport into human mesothelial cells (HMC) exposed to osmotic solutes.

Design

Using potassium analog 86Rb, we evaluated its intracellular transport through three pathways: 1. blocked by ouabain; 2. blocked by furosemide but not by ouabain; 3. blocked by neither furosemide nor ouabain. Experiments were performed in a normotonic medium (control) or in a medium supplemented with osmotic solutes (glucose, glycerol, mannitol). Both the acute and chronic effects of osmotic solutes on potassium transport were studied.

Results

The acute exposure of mesothelial cells to osmotic solutes modifies the intracellular transport of potassium through all studied channels, and the effect is specific for every solute. In mesothelial cells exposed over 7 days to glucose (90 mM), the intracellular transport via ouabain and furosemide-blocked channels is decreased, whereas it is increased through the third pathway. Total intracellular accumulation of 86Rb (potassium) ions in mesothelial cells cultured in a medium supplemented with various concentrations of glucose is decreased, and this effect is proportional to the concentration of glucose in the medium.

Conclusions

The intracellular transport of potassium in mesothelial cells is regulated through at least three independent mechanisms. Acute or chronic exposure of mesothelial cells to a hypertonic medium affects the intracellular accumulation of potassium, an d this effect is specific for the various osmotic solutes.

Keywords

Mesothelial cells potassium transport hyperosmolality

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References

De Weer

Cellular sodium-potassium transport. In: Seldin

D.W.

, Giebisch

, eds. The kidney, physiology and pathophysiology. New York: Raven, 1985: 31–48.

Van Bronswijk

, Verbrugh

H.A.

, Bos

H.J.

Cytotoxic effects of commercial continuous ambulatory peritoneal dialysis (CAPD) fluids and of bacterial exoproducts on human mesothelial cells in vitro.

Perit Dial Int 1989; 9: 197–202.

Lowry

, Rosenbrough

N.J.

, Farr

A.L.

Protein measurement with the Folin phenol reagent.

J Biol Chem 1951; 193: 265–75.

Schmidt

W.F.

III , McManus

T.J.

Ouabain-insensitive salt and water movement in duck red cells. III. The role of chloride in the volume response.

J Gen Physiol 1977; 70: 99–121.

Morgan

Effect of NaCl on composition and volume of cells of the rat papilla.

Am J Physiol 1977; 232: F117–22.

Macknight

A.D.C.

, Leaf

Cellular responses to extra cellular osmolality. In: Seldin

D.W.

, Giebisch

, eds. The kidney, physiology and pathophysiology. New York: Raven, 1985: 117–32.

Greene

D.A.

, Lattimer

S.A.

, Sigma

A.A.F.

Sorbitol, phosphoinositol and sodium-potassium ATPase in the pathogenesis of diabetic complications.

N Engl J Med 1987; 316: 599–606.

Yorek

M.A.

, Dunlap

J.A.

, Ginsberg

B.H.

The effect of increased glucose levels on Na-K pump activity in cultured neuroblastoma cells.

J Neurochem 1988; 51: 605–10.

Breborowicz

, Rodela

, Oreopoulos

D.G.

Toxicity of osmotic solutes on human mesothelial cells in vitro.

Kidney Int 1992; 41: 1280–5.

10.

Moreno

, Murphy

, Goldsmith

Increase in serum potassium resulting from the administration of hypertonic mannitol and other solutions.

J Lab Clin Med 1969; 73: 291–4.

11.

Lubin

Intracellular potassium and control of protein synthesis.

Fed Proc 1964; 23: 994–7.

In Vitro Study of the Mechanism of Potassium Transport into Human Mesothelial Cells. I: Effect of Hyperosmolality