Evidence for simultaneous 1Na+:1Mg2+ and ping pong 2Na+:1Mg2+ exchangers in rat thymocyte.

Rat thymocytes showed two Na+/Mg2+ exchangers with high- and low- affinities for external Na+ (Na+o) at physiological internal Mg2+content. The total internal Mg2+ content (Mg2+it) was enhanced by loading with MgCl2 and the ionophore A-23187. Under these conditions, Na+/Mg2+ exchangers were dramatically stimulated by the Mg2+it increase. Na+-induced Mg2+ effluxes were independent of Cl-o or H+. The Na+/Mg2+ exchangers, which we named HANao (high affinity for Na+o) and LANao (low affinity for Na+o), were dissected in Mg2+-loaded thymocytes according to their kinetics and stoichiometries. HANao, which showed an apparent dissociation constant for Na+o (KNa H) = 9.2 +/- 1.6 mmol l(-1) Na+o and a maximal Na+ influx rate (VNa(Na H)max) = 30.5 +/- 6.1 mmol (l cells)(-1) h(-1), was a 1Na+:1Mg2+ simultaneous antiporter insensitive to external magnesium (Mg2+o) whereas that LANao, with KNa L = 65.1 +/- 8.6 mmol l(-1) Na+ and a VNa(Na L)max = 79.5 +/- 14.3 mmol (l cells)(-1) Na+ h(-1), was a 2Na+:1Mg2+ "ping-pong" antiporter which was strongly inhibited by Mg2+o. At physiological concentration of Mg2+o (1 mM), the Na+/Mg2+ exchange through the LANao was inhibited by approximately 50%. Amiloride (10(-4) M) inhibited at similar extent both Na+ and Mg2+ fluxes at high and at low Na+o.

Fluorometric evidence for different stoichiometries for the Na+/Mg2+ exchange in Mg-loaded rat thymocytes.

The regulation of the cytosolic free magnesium concentration ([Mg2+]i) is a fundamental cellular process that requires magnesium extruding mechanisms. Here, we present evidence indicating that rat thymocytes are endowed with different Na/Mg exchange systems. Fluxes of magnesium were measured using the fluorescent magnesium indicator magfura-2. Cells were loaded with magnesium using the calcium ionophore A-23187 to 0.6-8.0 mM [Mg2+]i (resting [Mg2+]i = 0.38 +/- 0.06 mM, n = 5). The presence of extracellular sodium was required for magnesium exit. The initial rate of [Mg2+]i was stimulated by extracellular sodium with Michaelis-Menten kinetics. The Vmax of the sodium-dependent magnesium exit was markedly increased by [Mg2+]i. Holding the membrane potential at either -84 mV or at -10 mV had different effects on the sodium-stimulated magnesium efflux, depending on the extracellular sodium concentration ([Na+]o). At 10-30 mM [Na+]o, the magnesium efflux was faster at -10 mV than at -84 mV. Conversely, at 50-200 mM [Na+]o, the efflux of magnesium was faster at -84 mV that at -10 mV. At 75 mM [Na+]o, the activities where nearly the same at both membrane potential values. These observations suggest that the stochiometry of the Na+/Mg2+ exchange changes with [Na+]o.