Abstract
The transport of L-alanine was studied using membrane vesicles derived from the brush borders of the rabbit renal proximal tubule. Preincubation of the renal membranes with L-alanine, but not D-alanine, accelerated exchange diffusion of L-alanine, i.e. stereospecific counter transport. The equilibrium uptake of L-alanine decreased with increasing medium osmolarity. Extrapolation to infinite medium osmolarity, i.e. zero intravesicular space, indicates no uptake. These findings demonstrate that the uptake of L-alanine represents transport into membrane vesicles and not surface binding to the membrane. The presence of a Na+ gradient between the external incubation medium and the intravesicular medium stimulated L-alanine uptake. Accumulation of the amino acid in the vesicles was maximal at 5 min and then decreased, indicating efflux. The final level of uptake in the presence of the Na+ gradient was identical with that obtained in the absence of the gradient, suggesting that equilibrium was established. At the peak of the "overshoot" the uptake of L-alanine was slmost twice the final equilibrium value. These results suggest that the imposition of a large extravesicular to intravesicular gradient of Na+ effects the transient movement of L-alanine into renal brush border membrane vesicles against its concentration gradient. Stimulation of L-alanine uptake was specific for Na+. When the intravesicular medium contained no Na+, the rate of uptake enhanced with increases in the concentration of Na+ in the external medium. Increasing the Na+ gradient lowered the apparent Km for L-alanine. In the absence of the Na+ gradient, the rates of uptake of L- and D-alanine were identical. In the presence of the Na+ gradient, the rate of D-alanine uptake was stimulated, but significantly less than that of L-alanine. The uptake of L-alanine, at a given concentration of amino acid reflected the sum of the contributions from Na+ gradient-dependent and -independent transport systems. The dependent system was saturated at about 2 mM L-alanine. The independent system exhibited minimal saturability and may itself represent the sum of passive diffusion and a "carrier"-mediated system. At physiological concentrations of L-alanine, the rate of the Na+ gradient-dependent uptake was 5-fold that in the absence of the gradient. Valinomycin enhanced the Na+ gradient-dependent uptake of L-alanine, provided a K+ gradient (vesicle greater than medium) was present. This finding indicates that the Na+ gradient-dependent transport of L-alanine into renal brush border membrane vesicles is an electrogenic process and suggests that the membrane potential is a determinant of L-alanine transport. In the presence of a Na+ gradient, the uptake of L-alanine was strongly inhibited by other neutral L-amino-acids. Imino acids and glycine also inhibited, but acidic and basic amino acids were without effect. In the absence of a Na+ gradient, little selective competition was found...
Highlights
From the Laboratory of Molecular Aging, National Institute on Aging, National Baltimore City Hospitals, Baltimore, Maryland 21224
Alanine was almost twice the final equilibrium value. These results suggest that the imposition of a large extravesicular to intravesicular gradient of Na+ effects the transient movement of L-alanine into renal brush border membrane vesicles against its concentration gradient
The data presented in this study describe the uptake of the neutral amino acid L-alanine into isolated renal proximal tubule luminal membrane vesicles
Summary
In the absence of a Na+ gradient, little selective competition was found These findings indicate that the luminal membrane of the renal proximal tubule is a site which determines amino acid transport specificity. Renal transport of amino acids has been examined with a wide variety of physiological preparations, including the intact animal, tubular segments, and cortical slices [2] These studies indicate that, at least for some amino acids, transport in the kidney is an energy-dependent uphill system Na+ gradient-dependent, uphill, stereospecific, selective, and electrogenic These findings provide direct evidence on the mechanism by which L-alanine is transported across the luminal membrane into the renal proximal tubular cell
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