Assessment of protein turnover in perfused rat liver. Evidence for amino acid compartmentation from differential labeling of free and tRNA-gound valine.

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. Thus, 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 thus appears to eliminate much of the previous uncertainty in the quantitation of hepatic protein turnover. In the course of these studies we noted that 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 extracellular valine concentration and specific activity were held constant. The intracellular valine specific activity rose with a half-life of 1.2 min. By contrast, the rise in the specific activity of valyl-tRNA was biphasic: the initial phase of the valyl-tRNA curve was rapid, while the second phase had a half-life equal to that of intracellular valine. These data show that at physiological concentrations of valine, valyl-tRNA derives its amino acids from both the extracellular and cytoplasmic pools, and that 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.     

MEASUREMENTS OF IN VIVO RATES OF PROTEIN SYNTHESIS IN BRAIN, SPINAL CORD, HEART AND LIVER OF YOUNG VERSUS ADULT RATS, INTACT VERSUS HYPOPHYSECTOMIZED RATS

Abstract— In vivo protein synthesis rates in rats were estimated by single i.p. injections of large quantities of [1-¹⁴C]valine. This method gives reliable estimates of the precursor specific activity and average protein synthesis rates. In the brain, spinal cord, heart and liver, the average rates for adults were 0.65, 0.42, 0.49 and 1.92% replacement of protein-bound amino acid per h. In the brain and liver of 10-day olds the average rates were estimated to be 1.46 and 3.12% per h respectively. Hypophysectomy decreased synthesis rates by 25% or more in all tissues studied. The disadvantages of the method are that applying large amounts of valine i.p. appeared to constitute a stress and that the valine solution required for injection was hypertonic, causing withdrawal of body fluids of the animal.     

Effect of ethanol on hepatic phosphatidate phosphohydrolase: dose-dependent enzyme induction and its abolition by adrenalectomy and pyrazole treatment

Protein synthesis, measured as the incorporation of [¹⁴C]valine into cell proteins and into proteins secreted into the medium, and albumin production were studied in isolated rat liver hepatocytes. Protein synthesis was substantially higher in cells from fed rats than in cells from fasted rats. Addition of carbohydrates or amino acids increased protein synthesis in cells from fasted rats, whereas no effect was seen in cells from fed rats. Addition of oleate had no effect on protein synthesis. Ethanol inhibited protein synthesis in cells from fasted rats, whereas no or only small effect was seen in cells from fed rats. Simultaneous addition of carbohydrates diminished the inhibitory effect of ethanol, whereas addition of oleate increased the inhibitory effect of ethanol. It is suggested that the rate of protein synthesis in cells from fasted rats could be restricted by lack of precursors for synthesis of nonessential amino acids. The effect of ethanol is explained by an inhibition of gluconeogenesis.     

Analysis of effect of age on synthesis of specific proteins by hepatocytes

The effect of age on the synthesis of specific proteins by hepatocytes was studied in Fischer F344 rats using two-dimensional polyacrylamide gel electrophoresis. Almost all proteins synthesized by hepatocytes from young rats were synthesized by hepatocytes isolated from old rats. Of over 500 proteins visually compared by two-dimensional polyacrylamide gel electrophoresis, only 11 proteins were observed to disappear and/or appear consistently with increasing age. The rates of synthesis of 36 randomly chosen proteins were quantified. Interestingly, the synthesis of 35 of the 36 proteins decreased between 5 and 30 months of age. The decrease in protein synthesis varied (15% to 70%) from one protein to another; i.e., a heterogeneity was observed in the age-related decrease in the synthesis of proteins. The age-related decrease in protein synthesis was statistically significant for 53% of the proteins studied. The total decrease in the rate of synthesis of all 36 proteins studied was 40% between 5 and 30 months of age, which is essentially the same as the decrease in total protein synthesis by suspension of hepatocytes isolated from 5- and 30-month-old rats. The results of this study demonstrate that the mechanism underlaying aging is different from development, which is characterized by a major change in the species of proteins synthesized by a cell.     

Plasma protein synthesis by isolated rat hepatocytes

A system of preparation of rat hepatocytes with extended viability has been developed to study the role of hormones and other plasma components upon secretory protein synthesis. Hepatocytes maintained in minimal essential medium reduced the levels of all amino acids in the medium except the slowly catabolized amino acids leucine, isoleucine, and valine, which steadily increase as the result of catabolism of liver protein. Although the liver cells catabolize 10-15% of their own protein during a 20-h incubation, the cells continue to secrete protein in a linear fashion throughout the period. The effects of insulin, cortisol, and epinephrine on general protein synthesis, and specifically on fibrinogen and albumin synthesis, have been tested on cells from both normal rats and adrenalectomized rats. Cells from normal animals show preinduction of tyrosine amino transferase (TAT), having at the time of isolation a high level of enzyme which shows only an increase of approximately 60% upon incubation with cortisol. In contrast, cells from adrenalectomized animals initially have a low level of enzyme which increases fourfold over a period of 9 h. The effects of both epinephrine and cortisol on protein synthesis are also much larger in cells from adrenalectomized animals. After a delay of several hours, cortisol increases fibrinogen synthesis sharply, so that at the end of the 20-h incubation, cells treated with hormone have secreted nearly 2.5 times as much fibrinogen as control cells. The effect is specific; cortisol stimulates neither albumin secretion nor intracellular protein synthesis. The combination of cortisol and epinephrine strongly depresses albumin synthesis in both types of cells. Insulin enhances albumin and general protein synthesis but has little effect on fibrinogen synthesis.     

Effects of cycloheximide on protein degradation and gluconeogenesis in the perfused rat liver.

Cycloheximide at concentrations above 18 muM produced a 93% inhibition of total protein synthesis measured by valine incorporation in the perfused rat liver. Rates of protein degradation were estimated by perfusing livers prelabeled in vivo with L-[1-14C]valine with medium containing 15 mM L-valine. Thus labeled valine released from liver protein during perfusion was greatly diluted and reincorporation of label was minimized. Cycloheximide at 18 muM inhibited protein degradation by over 60%, after a delay of 15-20 min. Associated with these effects were dose-dependent increases in the rates of glucose and urea production. Glucose production increased 3 fold, from 0.54 +/- 0.07 in control to 1.85 +/- 0.24 mumol/min/100 g rat in cycloheximide-treated livers. Urea production increased from 0.24 +/- 0.02 to 0.62 +/- 0.06 mumol/min/100 g rat. No changes in liver glycogen or cyclic AMP content were seen. The data suggest that inhibition of protein synthesis provides an increased availability of intra-cellular amino acids and that many of these are rapidly degraded, yielding urea and glucose. This is supported by the fact that intracellular alanine levels were significantly increased following cycloheximide treatment. It is possible that the inhibition of protein degradation by cycloheximide is due to altered intra-cellular pools of amino acids or their metabolites.     

Amiloride inhibits protein synthesis in isolated rat hepatocytes

The effects of amiloride on Na⁺ ion influx, amino acid transport, protein synthesis and RNA synthesis have been studied in isolated rat hepatocytes. The initial rate of ²²Na⁺ uptake and the amount of ²²Na⁺ taken up at later time points were decreased in hepatocytes incubated in the presence of amiloride. Amiloride inhibited by about 25% the influx of α-methylamino[1?¹⁴C]isobutyric acid, a specific substrate for the A (Alanine preferring) system of neutral amino acid transport. By contrast, the activity of system L (Leucine preferring) was not affected by amiloride. Rates of protein synthesis were determined by using high extracellular concentrations of [¹⁴C]valine in order to maintain a constant amino acid precursor pool. Amiloride inhibited protein synthesis by 85% and had no effect on RNA synthesis. Half-maximal inhibition of protein synthesis occurred with amiloride at about 150 μM. In the absence of Na⁺ in the incubation medium, the rate of protein synthesis was reduced by about 35% and no further inhibition was observed with amiloride. These results suggest that in isolated rat hepatocytes protein synthesis is partially dependent on Na⁺, and that amiloride is an efficient inhibitor of protein synthesis.     

Preparation of (125I)-dCTP and its use as a substrate for RNA- and DNA-directed DNA synthesis.

Viable isolated parenchymal cells were incubated in a modified Waymouth medium under an oxygen tension of 30×10³ Pa at pH 7.8. Under these conditions, hepatocytes from 3-month-old rats synthesized 5.8 μg albumin/h/10⁶ cells. This value nearly equals the synthesizing capacity of intact liver tissue and is the highest activity reported so far for isolated hepatocytes. Parenchymal cells isolated from 36-month-old rats synthesized more albumin as compared to cells from 3-month-old rats. The albumin synthesizing capacity of cells isolated from 12-month-old rats was less than that of cells from 3-month-old rats.     

Elastin synthesis during perinatal lung development in the rat

The rate of soluble elastin synthesis was estimated in lung explants from rats of differing ages to better define periods in lung development important to the deposition of lung elastin. Lungs from rat pups at days 1, 3, 7, 9, 12, 15, and 21 post-parturition and from adult rats were incubated in a defined medium containing L-[3H]valine. Following incubation, labelled soluble elastin (tropoelastin) was separated from other soluble proteins by coacervation and electrophoresis on polyacrylamide gels containing sodium dodecyl sulfate. The tropoelastin synthetic rate was then estimated after correcting for differences in recovery of radioactivity as tropoelastin and lung tissue L-[3H]valine specific activity. Maximal rates of elastin synthesis were observed in lung explants from 7-12-day-old rats. The rate of elastin synthesis during this period was 5-8-times the rate observed in adult rat lung (expressed per g of fresh lung) and represented approx. 2% of the total protein synthesis. Moreover, the values derived from lung explant culture for elastin synthesis were consistent with values for lung elastin deposition in the perinatal rat (5-10 micrograms elastin/h per g lung).     

THE NATURE OF THE AMINO ACID POOL USED FOR PROTEIN SYNTHESIS IN RAT BRAIN SLICES

The incorporation into brain slice protein of externally provided [1-¹⁴C]valine was measured at varying levels of valine in the medium, under conditions of constant protein synthesis and equilibration of intracellular valine specific activity. The results indicate that the valine pool used for protein synthesis is not identical to the pool of total free valine. Neither does the incorporation solely occur from an extracellular pool which is in equilibrium with the incubation medium. The data are compatible with a two-site activation model in which aminoacylation of tRNA occurs at both an internal site utilizing amino acid from the intracellular pool and an external (possibly membranous) site converting extracellular valine directly to valyl-tRNA. A good fit to the experimental observations is also provided by a compartmented intracellular valine pool model.     

Incorporation of 13C,15N-labeled nucleosides and measurement of RNA synthesis and turnover in sea urchin embryos

The uptake of nucleosides into sea urchin embryos and their subsequent incorporation into RNA increases with increasing external nucleoside concentration. When embryos are incubated with high concentrations of ¹³C,¹⁵N-labeled nucleosides, newly synthesized RNA becomes sufficiently labeled with heavy isotope to be separated from unlabeled RNA on cesium formate equilibrium gradients. High concentrations of nucleosides do not affect development of embryos or rates of RNA synthesis. The extent of density-labeling of precursor pools increases with incubation time, and only levels off after many hours. During incubations with high concentrations of nucleosides, ATP pools expand up to twofold. Using density-labeling to circumvent precursor pool measurements, a method is presented to study the synthesis and decay of pulse-labeled RNA. The instantaneous rate of synthesis of total RNA at the blastula stage is 9.3 × 10^?15 mol of total nucleotide/embryo per minute and the average half-life of total RNA is 23 minutes.     

Incorporation of [3H]Leucine and [3H]Valine into Protein of Freshwater Bacteria: Uptake Kinetics and Intracellular Isotope Dilution

Incorporation of [³H]leucine and [³H]valine into proteins of freshwater bacteria was studied in two eutrophic lakes. Incorporation of both amino acids had a saturation level of about 50 nM external concentration. Only a fraction of the two amino acids taken up was used in protein synthesis. At 100 nM, the bacteria respired 91 and 78% of leucine and valine taken up, respectively. Respiration of ³H and ¹⁴C isotopes of leucine gave similar results. Most of the nonrespired leucine was recovered in bacterial proteins, while only up to one-half of the nonrespired valine occurred in proteins. In intracellular pools of the bacteria, [³H]leucine reached an isotope saturation of 88 to 100% at concentrations of >40 nM. For [³H]valine, an isotope equilibrium of about 90% was obtained at concentrations of >80 nM. Within an incubation period of typically 1 h, tritiated leucine and valine incorporated into proteins of the bacteria reached an isotope saturation of 2 to 6%. In a 99-h batch experiment, bacterial protein synthesis calculated from incorporation of leucine and valine corresponded to 31 and 51% (10 nM) and 89 and 97% (100 nM), respectively, of the chemically determined protein production. Measured conversion factors of 100 nM leucine and valine were 6.4 × 10¹⁶ and 6.6 × 10¹⁶ cells per mol, respectively, and fell within the expected theoretical values. The present study demonstrates that incorporation of both valine and leucine produces realistic measurements of protein synthesis in freshwater bacteria and that the incorporation can be used as a measure of bacterial production.     

Turnover of ethanolamine phosphoglycerides in different brain areas of adult and aged rats

The turnover of ethanolamine glycerophospholipids (EGP) has been determined in six different cerebral areas of 4-month and 22-month-old rats, by injecting [³H]glycerol together with [¹⁴C]ethanolamine into the lateral ventricle of the brain. The areas examined behave quite differently in respect to their utilization of the most simple precursors of phosphoglyceride biosynthesis. The incorporation of both glycerol and ethanolamine is already complete as early as 2–4 hours and then reutilization begins, at least for the so called fast pools of phosphoglycerides. The different slopes of the specific activity of the two precursors in EGP suggest a high degree of variance among catabolic rates in the different brain regions. In aged rats the utilization of the water-soluble precursors of EGP synthesis decreases in all brain areas and these data suggest that aging may have a different effect on the catabolic activities as well as phospholipid biosynthesis.     

In vivo rates of protein synthesis in brain,muscle, and liver of five vertebrate species

To compare cerebral protein metabolism rates in vivo, protein synthesis rates of three organs of five vertebrate species were measured after a single i.p. injection of a flooding dose of [1-¹⁴C]valine. In muscle, brain, and liver, the respective average protein synthesis rates, expressed as percent of total protein-bound valine replaced per hour, that is, percent synthesis per hour, in goldfish at 22°C body temperature, were 0.07, 0.23, and 0.57%; in the bullfrog at 20°C, 0.06, 0.18, and 0.55%; in the white Leghorn chicken at 39°C, 0.24, 0.70, and 2.17%; and in the mouse at 38°C, 0.22, 0.65, and 2.0%. In the Tokay lizard at different body temperatures, the synthesis rates were 0.04, 0.13, and 0.43% at 26°C; 0.05, 0.20, and 0.63% at 32°C; and 0.07, 0.27, and 0.81% at 38°C. The results demonstrate differences in protein synthesis rates in organs of the various species examined. The differences among the species seem to be due, to a major extent, to differences in body temperature; rates in lizard are below those in other species at temperatures tried. Protein synthesis rates in brain in all species are almost three times lower than those in liver and almost three times higher than those in muscle.     

Effect of Loading Doses of l-Valine on Relative Contributions of Valine Derived from Protein Degradation and Plasma to the Precursor Pool for Protein Synthesis in Rat Brain

"Flooding" amino acid pools with high doses of labeled amino acids of low specific activity has been proposed to minimize the effects of recycling of amino acids derived from protein degradation on the specific activity of the amino acid precursor pool for protein synthesis. We have examined the influence of recycling on the precursor pool for protein synthesis under conditions in which plasma valine concentrations were normal (0.19 mM) and "flooded" (10-28 mM) by comparing the steady-state specific activity of the tRNA-bound valine with that of the plasma valine. Under normal and "flooding" conditions, the relative contributions of valine from protein degradation to the precursor pool were 63 and 26%, respectively; "flooding" with a plasma level of 28 mM raised the brain acid-soluble pool level to 3.1 mM but was no more effective in decreasing the relative contribution of valine from protein degradation to the precursor pool than "flooding" with a plasma level of 17 mM valine, which raised the brain acid-soluble level only to 2.3 mM. The results of these studies show that "flooding" amino acid pools does indeed reduce the effect of recycling on the precursor amino acid pool for protein synthesis, but it does not totally eliminate it.     

Measurement of local rates of brain protein synthesis by quantitative autoradiography: Validation with L-[3H]valine

Following the injection of 4-day old rats with 150 mMl-[3,4-³H]valine (10mol/g, IP) the incorporation of³H into protein was linear 2 hours. Valine specific activity in the brain acid-soluble fraction was constant between 30 and 120 min after injection with a mean value of 82.3% of the injectate. Significant amounts of tritated metabolites accumulated in the brain acid-soluble fraction (41.4% of radioactivity at 120 min) but do not prove an impediment to measuring rates of protein synthesis. The rate of protein synthesis in cerebral cortex of the 4-day old rat was measured by quantitative autoradiography using [³H]valine and³H-sensitive film. The measured rate shows excellent agreement with that found previously usingl-[1-¹⁴C]valine. Our results suggest that [³H]valine can be a useful precursor to measure local rates of brain protein synthesis by quantitative autoradiography.     

Correlation between plasma membrane surface area and transferrin secretion rate in isolated hepatocytes

It is generally considered that in exocytosis the size of the secreting cells does not increase when the membranes of exocytosis vesicles fuse with the plasma membrane. As the factors involved in the regulation of this phenomenon are poorly understood, we thought it worthwhile to investigate the relationship between the plasma membrane surface area and secretory activity. Isolated rat hepatocytes were prepared by liver collagenase perfusion. Secretion of the plasma protein, transferrin (Tf) was detected at the single cell level with specific anti-rat transferrin antibodies using the reverse hemolytic plaque test. Hepatocyte surface and hemolytic ring surface areas were calculated from diameters of hepatocyte and hemolytic plaque measured after 5h of incubation. A highly significant correlation was established between the plaque-forming hepatocyte surface areas and the corresponding hemolytic surface areas. This result was confirmed using an automatic image analysis method. Two-month-old rats were compared to 4-month-old rats. We observed that the ratio of the quantity of transferrin secreted by hepatocytes to the hepatocyte surface area was constant for a given incubation time, whatever the size of the hepatocytes. These results suggest that the plasma membrane surface area of hepatocytes may constitute a limiting factor in Tf secretion.     

Compartmentation of free amino acids for protein biosynthesis. Influence of diurnal changes in hepatic amino acid concentrations of the composition of the precursor pool charging aminoacyl-transfer ribonucleic acid.

To investigate further the mechanisms by which amino acids are segregated for protein biosynthesis, the distribution of a pulse of [3H]valine was monitored in hepatic amino acid pools at seven intervals in the diurnal cycle of meal-fed rats. Although each condition was characterized by a unique balance between intracellular and extracellular valine, in every case the specific radioactivity of valyl-tRNA at steady state was higher that that of intracellular valine but below the extracellular value. Further, the specific radioactivity of the valyl-tRNA could be accurately predicted if extracellular and intracellular valine were combined in proportions specified by the transmembrane concentration gradient. These observations not only substantiate our earlier conclusions that the amino acids used for protein synthesis do not originate exclusively from either the intracellular or extracellular pools, but also strengthen our theory that the membrane transport system is the physical basis for such compartmentation. On the basis of these data we present a method for measuring the specific radioactivity of the precursor pool for protein biosynthesis in cases where the actual isolation of the aminoacyl-tRNA is not technically feasible, and also suggest a theoretical basis for interpreting the unequal distribution of both total and [3H]valine between intracellular and extracellular fluids.