Ca 2+ Transport by Mitochondria from L1210 Mouse Ascites Tumor Cells

Abstract

Mitochondria isolated from the ascites form of L1210 mouse leukemia cells readily accumulate Ca ²⁺ from the suspending medium and eject H ⁺ during oxidation of succinate in the presence of phosphate and Mg ²⁺ , with normal stoichiometry between Ca ²⁺ uptake and electron transport. Ca ²⁺ loads up to 1600 ng-atoms per mg of protein are attained. As is the case in mitochondria from normal tissues, Ca ²⁺ uptake takes precedence over oxidative phosphorylation. However, Ca ²⁺ transport by the L-1210 mitochondria is unusual in other respects, which may possibly have general significance in tumor cells. The apparent affinity of the L1210 mitochondria for Ca ²⁺ in stimulation of oxygen uptake is about 3-fold greater than in normal liver mitochondria; moreover, the maximal rate of Ca ²⁺ transport is also considerably higher. Furthermore, when Ca ²⁺ pulses are added to L1210 mitochondria in the absence of phosphate or other permeant anions, much larger amounts of Ca ²⁺ are bound and H ⁺ ejected per atom of oxygen consumed than in the presence of phosphate; up to 7 Ca ²⁺ ions are bound per pair of electrons passing each energy-conserving site of the electron-transport chain. Such “superstoichiometry” of Ca ²⁺ uptake can be accounted for by two distinct types of respiration-dependent interaction of Ca ²⁺ with the L1210 mitochondria. One is the stimulation of oxygen consumption, which is achieved by relatively low concentrations of Ca ²⁺ ( K _m ≅ 8 μM) and is accompanied by binding of Ca ²⁺ up to 40 ng-atoms per mg of protein. The second process, also dependent on electron transport, is the binding of further Ca ²⁺ from the medium in exchange with previously stored membrane-bound protons, in which the affinity for Ca ²⁺ is much lower ( K _m ≅ 120 μM).