ASSESSMENT OF PROTEIN TURNOVER IN PERFUSED RAT-LIVER - EVIDENCE FOR AMINO-ACID COMPARTMENTATION FROM DIFFERENTIAL LABELING OF FREE AND TRANSFER-RNA-BOUND VALINE

Abstract

Total protein synthesis in perfused livers of fed rats was determined by measuring the rate of valine incorporation based on the specific activity of valine attached to tRNA. Rates were not significantly altered when perfusate valine was increased from 0.40 to 5 mM and were similar to values calculated earlier from the specific activity of extracellular valine at a concentration of 15 mM. Overall protein degradation, computed from the sum of the rates of synthesis and the total increase of free intra- and extracellular valine, corresponded closely to the increase of free valine that occurred between 5 and 15 min after the addition of cycloheximide. In the latter experiments advantage was taken of the fact that the previously established suppressive effect of cycloheximide on proteolysis does not begin initially with the inhibition of synthesis, but 15 min later. The release of valine from 5 to 15 min was assumed to represent rates of protein degradation in effect prior to the addition of cycloheximide. The close agreement found among these independent assessments of protein metabolism appears to eliminate much of the previous uncertainty in the quantitation of hepatic protein turnover. The specific activity of valyl-tRNA attained steady state values that were intermediate between specific activities of the extracellular and intracellular pools, but appeared to reach a steady state sooner than that of intracellular valine. To evaluate these early events more precisely, the specific activity of valine in tRNA and the intracellular pool was measured in a series of single-pass perfusion experiments where extracelluar valine concentration and specific activity were held constant. The intracellular valine specific activity rose with a half-life of 1.2 min. The rise in the specific activity of valyl-tRNA was biphasic: the initial phase of the valyl-tRNA curve was rapid, while the 2nd phase had a half-life equal to that of intracellular valine. At physiological concentrations of valine, valyl-tRNA derives its amino acids from both the extracellular and cytoplasmic pools, and at least some tRNA is charged by extracellular amino acids before they mix with intracellular amino acid pools, possibly from a precursor pool at or near the cell membrane.