J. Biol. Chem., Vol. 259, Issue 12, 7563-7569, Jun, 1984

The regulation of cytoplasmic pH in human fibroblasts

WH Moolenaar, LG Tertoolen and SW de Laat

The regulation of cytoplasmic pH (pHi) has been examined in normal human foreskin fibroblasts (HF cells) using a fluorometric technique for continuously monitoring rapid pHi transients. We previously reported that pHi in HF cells is rapidly raised by growth factors due to activation of a Na+/H+ exchange mechanism in the plasma membrane ( Moolenaar , W. H., Tsien , R. Y., van der Saag , P. T., and de Laat , S. W. (1983) Nature (Lond.) 304, 645-648). Here we characterize the ionic basis of pHi homeostasis in quiescent HF cells. When HF cells are acid-loaded by externally applied weak acids or by pretreatment with NH4+, pHi immediately recovers toward its resting value (approximately 7.05). pHi recovery follows an exponential time course and is accompanied by enhanced Na+ influx and net H+ extrusion. Recovery of pHi and concomitant Na+/H+ fluxes are reversibly inhibited by amiloride (half-maximal effect at approximately 0.1 mM). The rate of pHi recovery from an acid load depends on external Na+ (half-maximal rate at approximately 35 mM), but is independent of external anions (HCO3-, Cl- ) and is not affected by membrane depolarization. Li+ can substitute for Na+ in pHi recovery. In Na+-free media, pHi spontaneously falls to a new resting value, from which it rapidly recovers after readdition of Na+. A stepwise increase in external pH (pHo) accelerates pHi recovery from an acid load and raises the resting pHi by approximately 50% of the pHo shift. The response of pHi to alkaline pHo shifts is abolished by amiloride and by Na+ removal. It is concluded that pHi in HF cells is closely regulated by an amiloride-sensitive, reversible Na+/H+ exchanger, which is driven by the transmembrane concentration gradients for Na+ and H+. Under normal conditions, the exchanger appears to be relatively inactive, while its rate is increasingly stimulated by lowering pHi or by raising pHo.
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