Membrane potential,anion and cation conductances in Ehrlich ascites tumor cell

Summary The fluorescence intensity of the dye 1,1-dipropyloxadicarbocyanine (DiOC₃-(5)) has been measured in suspensions of Ehrlich ascites tumor cells in an attempt to monitor their membrane potential (V_m) under different ionic conditions, after treatment with cation ionophores and after hypotonic cell swelling. Calibration is performed with gramicidin in Na⁺-free K⁺/choline⁺ media, i.e., standard medium in which NaCl is replaced by KCl and cholineCl and where the sum of potassium and choline is kept constant at 155mm. Calibration by the valinomycin null point procedure described by Lariset al. (Laris, P.C., Pershadsingh, A., Johnstone, R.M., 1976,Biochim. Biophys. Acta436:475–488) is shown to be valid only in the presence of the Cl^–-channel blocker indacrinone (MK196). Distribution of the lipophilic anion SCN^– as an indirect estimation of the membrane potential is found not to be applicable for the fast changes inV_m reported in this paper. Incubation with DiOC₃-(5) for 5 min is demenstrated to reduce the Cl^– permeability by 26±5% and the NO₃^– permeability by 15±2%, while no significant effect of the probe could be demonstrated on the K⁺ permeability. Values forV_m, corrected for the inhibitory effect of the dye on the anion conductance, are estimated at –61±1 mV in isotonic standard NaCl medium, –78±3 mV in isotonic Na⁺-free choline medium and –46±1 mV in isotonic NaNO₃ medium. The cell membrane is depolarized by addition of the K⁺ channel inhibitor quinine and it is hyperpolarized when the cells are suspended in Na⁺-free choline medium, indicating thatV_m is generated partly by potassium and partly by sodium diffusion. Ehrlich cells have previously been shown to be more permeable to nitrate than to chloride. Substituting NO₃^– for all cellular and extracellular Cl^– leads to a depolarization of the membrane, demonstrating thatV_m is also generated by the anions and that anions are above equilibrium. Taking the previously demonstrated single-file behavior of the K⁺ channels into consideration, the membrane conductances in Ehrlich cells are estimated at 10.4 S/cm² for K⁺, 3.0 S/cm² for Na⁺, 0.6 S/cm² for Cl^– and 8.7 S/cm² for NO₃^–. Addition of the Ca²⁺-ionophore A23187 results in net loss of KCl and a hyperpolarization of the membrane, indicating that the K⁺ permeability exceeds the Cl^– permeability also after the addition of A23187. The K⁺ and Cl^– conductances in A23187-treated Ehrlich cells are estimated at 134 and 30 S/cm², respectively. The membrane potential is depolarized in hypotonically swollen cells, confirming that the increase in the Cl^– permeability following hypotonic exposure exceeds the concommitant increase in the K⁺ permeability. In control experiments where the membrane potentialV_m=E_K=E_Cl=E_Na, it is demonstrated that cell volume changes has no significant effect on the fluorescence signal, apparently because of a large intracellular buffering capacity. The increase in the Cl^– conductances is 68-fold when cells are transferred to a medium with half the osmolarity of the standard medium, as estimated from the net Cl^– efflux and the change inV_m. The concommitant increase in the K⁺ conductance, as estimated from the net K⁺ efflux, is only twofold.