Sodium influx in serum-deprived human fibroblasts is by way of a pathway which shows saturation kinetics. A plot of initial Na influx versus [Na]0 ([Na]i approximately equal to 10 mM) gives a simple Michaelis-Menten type of curve with a K1/2 = 70.0 +/- 8.1 mM and a Vmax = 14.5 +/- 1.9 mumol/g prot/min. A similar plot of initial Na influx versus [Na]0 in the presence of 10% fetal bovine serum (FBS) gives a nonsaturating curvilinear response which appears to be biphasic. A plot of the serum-dependent Na influx versus [Na]0 (obtained by subtracting the curve in the absence of FBS from the curve in the presence of 10% FBS) shows that there is a linear relationship between serum-induced Na influx and external [Na]. At physiological Na concentrations, in the presence of FBS, the serum-induced Na influx is equal to the amiloride-sensitive Na flux, whereas in the absence of serum amiloride inhibits less than 10% of the Na influx. The effect of intracellular Na on Na flux was tested by preloading cells with Na in a digitoxin-containing medium prior to measurement of Na flux. A plot of steady-state Na exchange flux versus [Na]0 ([Na]i approximately equal to [Na]0) in the absence of serum gives a curve that appears to saturate at approximately 100 mM Na (flux = 100 mumol/g prot/min) and then declines with increasing [Na] (flux = 40 mumol/g prot/min at 150 mM). In contrast to Na influx in control serum-deprived cells, Na flux in Na-loaded cells in dramatically inhibited by the presence of amiloride. Since the peak Na exchange flux of 100 mumol/g prot/min is greatly in excess of the Vmax for Na influx in control serum-deprived cells and the enhanced Na flux is amiloride-sensitive, elevating intracellular Na must somehow activate the amiloride-sensitive Na transport system, which is normally only minimally active in the absence of serum.