Abstract
We have investigated the kinetic properties of the human red blood cell Na+/H+ exchanger to provide a tool to study the role of genetic, hormonal and environmental factors in its expression as well as its functional properties in several clinical conditions. The present study reports its stoichiometry and the kinetic effects of internal H+ (Hi) and external Na+ (Nao) in red blood cells of normal subjects. Red blood cells with different cell Na+ (Nai) and pH (pHi) were prepared by nystatin and DIDS treatment of acid-loaded cells. Unidirectional and net Na+ influx were measured by varying pHi (from 5.7 to 7.4), external pH (pHo), Nai and Nao and by incubating the cells in media containing ouabain, bumetanide and methazolamide. Net Na+ influx (Nai less than 2.0 mmol/liter cell, Nao = 150 mM) increased sigmoidally (Hill coefficient 2.5) when pHi fell below 7.0 and the external pHo was 8.0, but increased linearly at pHo 6.0. The net Na+ influx driven by an outward H+ gradient was estimated from the difference of Na+ influx at the two pHo levels (pHo 8 and pHo 6). The H+-driven Na+ influx reached saturation between pHi 5.9 and 6.1. The Vmax had a wide interindividual variation (6 to 63 mmol/liter cell.hr, 31.0 +/- 3, mean +/- SEM, n = 20). The Km for Hi to activate H+-driven Na+ influx was 347 +/- 30 nM (n = 7). Amiloride (1 mM) or DMA (20 microM) partially (59 +/- 10%) inhibited red cell Na+/H+ exchange. The stoichiometric ratio between H+-driven Na+ influx and Na+-driven H+ efflux was 1:1. The dependence of Na+ influx from Nao was studied at pHi 6.0, and Nai lower than 2 mmol/liter cell at pHo 6.0 and 8.0. The mean Km for Nao of the H+-gradient-driven Na+ influx was 55 +/- 7 mM. An increase in Nai from 2 to 20 mmol/liter cell did not change significantly H+-driven net Na+ influx as estimated from the difference between unidirectional 22Na influx and efflux. Na+/Na+ exchange was negligible in acid-loaded, DIDS-treated cells. Na+ and H+ efflux from acid-loaded cells were inhibited by amiloride analogs in the absence of external Na+ indicating that they may represent nonspecific effects of these compounds and/or uncoupled transport modes of the Na+/H+ exchanger. It is concluded that human red cell Na+/H+ exchange performs 1:1 exchange of external Na+ for internal protons, which is partially amiloride sensitive.(ABSTRACT TRUNCATED AT 400 WORDS)
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