Protein turnover and cellular autophagy in growing and growth-inhibited 3T3 cells

The relationship between growth, protein degradation, and cellular autophagy was tested in growing and in growth-inhibited 3T3 cell monolayers. For the biochemical evaluation of DNA and protein metabolism, growth-inhibited 3T3 cell monolayers with high cell density and growing 3T3 cell monolayers with low cell density were labeled simultaneously with [14C]thymidine and [3H]leucine. The evaluation of the DNA turnover and additional [3H]thymidine autoradiography showed that 24 to 5% of 3T3 cells continue to replicate even in the growth-inhibited state, where no accumulation of protein and DNA can be observed. Cell loss, therefore, has to be assumed to compensate for the ongoing cell proliferation. When the data of protein turnover were corrected for cell loss, it was found that the rate constant of protein synthesis in nongrowing monolayers was reduced to half the value found in growing monolayers. Simultaneously, the rate constant of protein degradation in nongrowing monolayers was increased to about 1.5-fold the value of growing monolayers. In parallel to the increased rate constant of protein degradation, the cytoplasmic volume fraction of early autophagic vacuoles (AVs) as determined by electron microscopic morphometry was found to be increased twofold in nongrowing 3T3 cell monolayers when compared with the volume fraction of early AVs in growing 3T3 cell monolayers. These data are in agreement with the assumption that cellular autophagy represents a major pathway of regulating protein degradation in 3T3 cells and that the regulation of autophagic protein degradation is of relevance for the transition from a growing to a nongrowing state.     

Membranes of animal cells. II. The metabolism and turnover of the surface membrane

Turnover studies of the surface membrane and of cell particulate matter of L cells in tissue culture in logarithmic and plateau phase of growth have been made. The rate of incorporation of isotope into these fractions and the rate of fall of specific activities of labeled L-cell fractions have been observed. The following interpretation of the data appears most likely although other interpretations are possible. Growing and nongrowing cells synthesize approximately similar amounts of surface membrane and particulate material. In the growing cell the material is incorporated with net increases in substance. There is relatively little turnover. In the nongrowing cell newly synthesized material is incorporated, but a corresponding amount of material is eliminated so that there is turnover without net increase of substance. Our results suggest that there is no gross differential turnover between the protein, lipid, and carbohydrate of the surface membrane under the conditions of our experiments. Metabolic inhibitors or omission of amino acids in the culture medium lead to a decrease in synthesis of surface membrane and cell particulates and cause an equivalent decrease in the rate of degradation of surface membrane and of particulates; therefore the synthetic and degradative aspects of turnover appear to be coupled. As cultures of nongrowing cells in suspension or on a glass surface age, their synthetic and turnover capacities diminish. Our results suggest that the cell may exist in a nongrowing state with a level of synthesis similar to that of a growing cell. It can exist in this state with a high level of turnover.     

Parallel changes in protein synthesis and messenger RNA content in growing and resting epithelial cells of Xenopus laevis

The regulation of cell growth can be achieved at many levels but ultimately the regulatory factors must alter protein synthesis since growing cells always exhibit an increased rate of protein synthesis compared to resting cells. Some studies using growing and nongrowing mammalian cells have shown that the rate of protein synthesis compared to resting cells. Some studies using growing and nongrowing mammalian cells have shown that the rate of protein synthesis is directly dependent on mRNA content. Other studies have shown that growing and resting cells have similar amounts of mRNA and that protein synthesis is regulated by the proportion of mRNA in polysomes. We have analyzed mRNA content in growing and resting epithelial cells of Xenopus laevis. Quantitation of poly(A)⁺ mRNA by uniform labeling with ³H-uridine and by ³H-poly(U)hybridization demonstrated a direct relationship between mRNA content and the relative rate of protein synthesis in growing and resting cells. Likewise, after serum stimulation of resting cells the increase in mRNA content closely paralleled the increase in protein synthesis. Our results suggest that control of protein synthesis in growing and nongrowing cells is exerted before the translational level.     

Somatotropin increases protein balance by lowering body protein degradation in fed, growing pigs

Somatotropin (ST) administration enhances protein deposition in well-nourished, growing animals. To determine whether the anabolic effect is due to an increase in protein synthesis or a decrease in proteolysis, pair-fed, weight-matched ( approximately 20 kg) growing swine were treated with porcine ST (150 microg. kg(-1). day(-1), n = 6) or diluent (n = 6) for 7 days. Whole body leucine appearance (R(a)), nonoxidative leucine disposal (NOLD), urea production, and leucine oxidation, as well as tissue protein synthesis (K(s)), were determined in the fed steady state using primed continuous infusions of [(13)C]leucine, [(13)C]bicarbonate, and [(15)N(2)]urea. ST treatment increased the efficiency with which the diet was used for growth. ST treatment also increased plasma insulin-like growth factor I (+100%) and insulin (+125%) concentrations and decreased plasma urea nitrogen concentrations (-53%). ST-treated pigs had lower leucine R(a) (-33%), leucine oxidation (-63%), and urea production (-70%). However, ST treatment altered neither NOLD nor K(s) in the longissimus dorsi, semitendinosus, or gastrocnemius muscles, liver, or jejunum. The results suggest that in the fed state, ST treatment of growing swine increases protein deposition primarily through a suppression of protein degradation and amino acid catabolism rather than a stimulation of protein synthesis.     

Effects of platelet-derived growth factor on degradation, nuclear translocation of nonhistone proteins, and DNA synthesis.

Stimulation of resting normal rat kidney fibroblasts, prelabeled with [3H]leucine, by platelet-derived growth factor (PDGF) caused inhibition of cellular protein degradation and a parallel increased nuclear translocation of 3H-labeled nonhistone proteins (3H-NHP) and DNA synthesis. Nuclear translocation of these proteins was independent of protein synthesis. Fractionation of the nuclear 3H-NHP in a pH gradient of 2.5-6.5 showed that the protein fractions with a high degree of proteolysis in resting cells corresponded to the protein fractions with a high extent of translocation in stimulated cells, suggesting that degradation and translocation of these proteins may be related. PDGF inhibited cellular uptake of [3H]chloroquine, suggesting that PDGF inhibits NHP degradation via the lysosomal pathway. These observations support the hypothesis that PDGF induces NHP translocation to the nucleus by inhibiting lysosomal degradation of these proteins.     

Vectorial transport of proteins by membrane-bound ribosomes of nongrowing and growing Jerusalem artichoke tuber cells

Both nongrowing (water-incubated) and growing (hormonally stimulated) Jerusalem artichoke tuber cells contain membrane-bound (mb) ribosomes. Using a rapid flotation procedure, a membrane fraction was prepared from both types of cells. This fraction was enriched in mb ribosomes, contained NADH cytochrome c reductase activity, had RNA:phospholipid and RNA:protein ratios similar to those reported for rough microsomes from animal tissues, and supported synthesis of preinitiated proteins in vitro. Using puromycin and detergent release, vectorial transport of labelled polypeptides was measured in the in vitro system. Of proteins made by mb ribosomes from nongrowing cells, on 12% remained associated with microsome membranes following chain termination. The comparable figure for proteins from mb ribosomes of growing tissue was 42%. The membrane-associated proteins were preferentially protected from protease digestion. Some possible reasons are suggested for the correlation between cell growth and the association of newly synthesized proteins with microsomes. The role of proteins synthesized by mb ribosomes but not vectorially transported, in both growing and nongrowing cells, is unknown.     

Thyroid hormones and muscle protein turnover. The effect of thyroid-hormone deficiency and replacement in thryoidectomized and hypophysectomized rats.

We have investigated the effects of thyroidectomy, hypophysectomy and 3,3',5-tri-iodothyronine replacement on protein synthesis and degradation in skeletal muscle in vivo. Thyroidectomy resulted in a decrease in the rate of protein synthesis as a result of a loss of RNA. However, RNA activity, the rate of protein synthesis per unit of RNA, was not decreased. This was the case in both young growing rats and mature nongrowing rats. Tri-iodothyronine treatment of thyroidectomized rats increased protein synthesis by increasing RNA concentration without changes in RNA activity, and this occurred even when food intake was restricted to prevent any increase in growth. The rate of protein degradation was decreased by thyroidectomy and increased by tri-iodo-thyronine replacement in both animals fed ad libitum and food-restricted animals. Hypophysectomy decreased protein synthesis by decreasing both RNA concentration and activity. these changes were reversed by tri-iodothyronine treatment even in the presence of persistent marked hypoinsulinaemia. This indicates that tri-iodothyronine can activate athe translational phase of protein synthesis in muscle in the absence of significant quantities of insulin. However, tri-iodothyronine does not seem to be obligatory for the maintenance of normal RNA activity in muscle, since in the thyroidectomized rat, in which plasma insulin concentrations are normal, RNA activity is maintained. From a consideration of the magnitude of changes in RNA activity observed in these experiments, it would appear that alterations in rates of elongation as well as initiation are involved in the changes in RNA activity.     

Induction of autolysis in nongrowing Escherichia coli

Unless relaxation of the stringent response is achieved, all nongrowing bacteria rapidly develop resistance to autolysis induced by a variety of agents, including all classes of cell wall synthesis inhibitors. We now describe inhibitors of cell wall synthesis which were unusual in that they could continue to effectively induce autolysis in relA+ Escherichia coli even after prolonged amino acid starvation. The process of cell wall degradation seems to be catalyzed by similar hydrolytic enzymes in nongrowing and growing cells, yet the activity of these new agents capable of inducing autolysis in the nongrowing relA+ cells did not involve relaxation of RNA or peptidoglycan synthesis. We propose that the suppression of autolysis characteristic of nongrowing cells can be bypassed by a novel mechanism of autolytic triggering which is independent of the relA locus.     

Changes in nucleic acid and protein synthesis during starvation and spherule formation inPhysarum polycephalum

Summary The synthesis of protein and nucleic acids was studied by isotope incorporation and dilution in the plasmodia ofPhysarum polycephalum during periods of growth and differentiation (spherule formation). The total protein content decreased during starvation, but protein synthesis still occurred, probably at the expense of proteins previously synthesized during growth. Studies on leucine incorporation showed that protein synthesized during growth had a greater turnover than did protein formed by starving cultures, when both types of cultures were transferred to starvation conditions. Protein synthesis after prolonged starvation was rapidly and markedly decreased following the inhibition of RNA synthesis, whereas no such direct dependence on RNA synthesis was observed in growing cultures or during early starvation.The kinetics of RNA synthesis and the types of RNA formed were also shown to differ in growth and starvation. RNA turnover was low in growing cultures but substantial in starving cultures that were returned to growth medium. Qualitative differences in pulse-labeled RNA extracted from growing or starving cultures were revealed by methylated-albumin-kieselguhr column chromatography and sucrose gradient centrifugation. In starving cultures proportionately more labeled RNA was found in the lighter, non-ribosomal region of the gradient, and RNA from this region hybridized with denatured DNA to a greater extent than did other RNA fractions.This work was supported in part by Grant CA-07175 from the National Cancer Institute and by a grant from the Alexander and Margaret Stewart Trust Fund. The authors express their appreciation to Dr. H. Kubinski for helpful suggestions.One of us (H.W.S.) was in part supported by the Deutsche Forschungsgemeinschaft.     

Effect of leucine-rich dietary protein on in vitro protein synthesis in porcine muscle

Experiments were conducted to determine the effect of feeding diets containing leucine-rich proteins on in vitro protein synthesis in porcine muscle. Swine (10 kg initial weight) were fed for 4 weeks diets composed mainly of corn gluten meal, corn and soybean meal, and containing a total of 2.00, 2.33, 2.92, 3.12, 3.53, and 4.01% leucine. At the end of the growing period, six swine fed each diet were killed and samples of biceps femoris, longissimus dorsi, and triceps brachii were excised. Incorporation of [14C]phenylalanine into newly synthesized protein was measured using a cell-free in vitro system following recombination of purified soluble protein and ribosomal fractions. The feeding of diets containing increasing amounts of leucine-rich protein increased the free leucine concentration in plasma and skeletal muscle. There was no significant effect of diet on incorporation of [14C]phenylalanine into muscle protein following simple recombination of soluble protein and ribosomal fractions from the same tissues. Combination of muscle soluble protein from animals fed 2.00% leucine with ribosomal fractions of animals fed increasing quantities of leucine-rich protein, however, indicated increased protein synthetic activity of the ribosomal fraction in all muscles tested. Protein synthetic activity of the soluble protein fraction was not affected by diet. It was concluded that the feeding of leucine-rich dietary proteins beyond requirements for maximal rate of growth can increase the protein synthetic potential of porcine muscle cells although whole body growth is depressed.     

Effects of fibroblastic growth factor on protein degradation, the migration of non-histone proteins to the nucleus and DNA synthesis in diploid fibroblasts

Stimulation of resting WI38 cells, prelabeled with [3H]leucine, with fibroblastic growth factor (FGF) or serum, caused increased nuclear translocation of [3H]non-histone proteins [( 3H]NHP) and DNA synthesis, and a parallel decrease of proteolysis. [3H]NHP migration was independent of protein synthesis. Fractionation of the nuclear proteins in a pH gradient of 2.5-6.5 showed that [3H]NHP fractions with high degradation rates in resting cells corresponded to the [3H]NHP fractions with high migration rates in stimulated cells, suggesting that degradation and migration of [3H]NHP are linked. FGF inhibited cellular uptake of [3H]chloroquine, suggesting that FGF inhibits NHP degradation via lysosomes. The lysosomotropic amine eserine had similar effects as FGF. It is proposed that FGF induces NHP migration to the nucleus by inhibiting their lysosomal degradation. FGF also caused migration of [3H]histones, however, the mechanism is not clear.     

Role of cell-wall biogenesis in the initiation of auxin-mediated growth in coleoptiles of Zea mays L.

The involvement of cell-wall polymer synthesis in auxin-mediated elongation of coleoptile segments from Zea mays L. was investigated with particular regard to the growth-limiting outer epidermis. There was no effect of indole acetic acid (IAA) on the incorporation of labeled glucose into the major polysaccharide wall fractions (cellulose, hemicellulose) within the first 2 h of IAA-induced growth. 2,6-Dichlorobenzonitrile inhibited cellulose synthesis strongly but had no effect on IAA-induced segment elongation even after a pretreatment period of 24 h, indicating that the growth response is independent of the apposition of new cellulose microfibrils at the epidermal cell wall. The incorporation of labeled leucine into total and cell-wall protein of the epidermis was promoted by IAA during the first 30 min of IAA-induced growth. Inhibition of IAA-induced growth by protein and RNA-synthesis inhibitors (cycloheximide, cordycepin) was accompanied by an inhibition of leucine incorporation into the epidermal cell wall during the first 30 min of induced growth but had no effect on the concomitant incorporation of monosaccharide precursors into the cellulose or hemicellulose fractions of this wall. It is concluded that at least one of the epidermal cell-wall proteins fulfills the criteria for a growth-limiting protein induced by IAA at the onset of the growth response. In contrast, the synthesis of the polysaccharide wall fractions cellulose and hemicellulose, as well as their transport and integration into the growing epidermal wall, appears to be independent of growth-limiting protein and these processes are therefore no part of the mechanism of growth control by IAA.Abbreviations CHI cycloheximide - COR cordycepin - DCB 2,6-dichlorobenzonitrile - GLP growth-limiting protein(s) - IAA indole-3-acetic acid     

Involvement of Protein Kinase C Activation in L-Leucine-Induced Stimulation of Protein Synthesis in L6 Myotubes

Effects of leucine and related compounds on protein synthesis were studied in L6 myotubes. The incorporation of [³H]tyrosine into cellular protein was measured as an index of protein synthesis. In leucine-depleted L6 myotubes, leucine and its keto acid, α-ketoisocaproic acid (KIC), stimulated protein synthesis, while D-leucine did not. Mepacrine, an inhibitor of both phospholipases A₂ and C, canceled stimulatory actions of L-leucine and KIC on protein synthesis. Neither indomethacin, an inhibitor of cyclooxygenase, nor caffeic acid, an inhibitor of lipoxygenase, diminished their stimulatory actions, suggesting no involvement of arachidonic acid metabolism. Conversely, 1-O-hexadecyl-2-O-methylglycerol, an inhibitor of proteinkinase C, significantly canceled the stimulatory actions of L-leucine and KIC on protein synthesis, suggesting an involvement of phosphatidylinositol degradation and activation of protein kinase C. L-Leucine caused a rapid activation of protein kinase C in both cytosol and membrane fractions of the cells. These results strongly suggest that both L-leucine and KIC stimulate protein synthesis in L6 myotubes through activation of phospholipase C and protein kinase C.     

In vivo measurements of the contributions of protein synthesis and protein degradation in regulating cardiac pressure overload hypertrophy in the mouse

Cardiac hypertrophy is generated in response to hemodynamic overload by altering steady-state protein metabolism such that the rate of protein synthesis exceeds the rate of protein degradation. To determine the relative contributions of protein synthesis and degradation in regulating cardiac hypertrophy in mice, a continuous infusion strategy was developed to measure myocardial protein synthesis rates in vivo. Osmotic mini-pumps were implanted in the abdominal cavity to infuse radiolabeled leucine in mice that are conscious and ambulatory. Protein synthesis rates were calculated by measuring incorporation of leucine into myocardial protein over 24 h prior to each time point and dividing by the specific radioactivity of plasma leucine. Compared to sham-operated controls, fractional rates of protein synthesis (K(s)) increased significantly at days 1 and 3 of TAC, but was lower on day 7 and returned to control values by day 14. These changes coincided with the curvilinear increase in LV mass that characterizes the hypertrophic response. Fractional rates of protein degradation (K(d)) were calculated by subtracting the rate of myocardial growth from the corresponding K(s) value. K(d) fell at days 1 and 3 of TAC, increased at day 7 and returned to control on day 14. Thus, the increase in LV mass generated in response to pressure overload is caused by acceleration of K(s) and suppression of K(d). As the growth rate slows, a new steady-state is achieved once the hypertrophic response is completed.     

Regulation of muscle protein degradation,not synthesis,by dietary leucine in rats fed a protein-deficient diet

The aim of this study was to elucidate the effects of long-term intake of leucine in dietary protein malnutrition on muscle protein synthesis and degradation. A reduction in muscle mass was suppressed by leucine-supplementation (1.5% leucine) in rats fed protein-free diet for 7 days. Furthermore, the rate of muscle protein degradation was decreased without an increase in muscle protein synthesis. In addition, to elucidate the mechanism involved in the suppressive effect of leucine, we measured the activities of degradation systems in muscle. Proteinase activity (calpain and proteasome) and ubiquitin ligase mRNA (Atrogin-1 and MuRF1) expression were not suppressed in animals fed a leucine-supplemented diet, whereas the autophagy marker, protein light chain 3 active form (LC3-II), expression was significantly decreased. These results suggest that the protein-free diet supplemented with leucine suppresses muscle protein degradation through inhibition of autophagy rather than protein synthesis.     

Uptake of (14C) leucine and protein synthesis in potato tuber buds and effect of abscisic acid on these processes]

The uptake of [14C] leucine and its incorporation into proteins of dormant and growing potato tuber buds were studied. It was found that the label uptake was increased at the beginning of the growth period, whereas the dynamics of this process were not changed in comparison with the dormant buds samples. The rate of [14C] leucine incorporation into proteins was increased in the growing buds; this increase was not, however, due to the increase in the uptake of the labelled precursor and was probably caused by activation of the protein synthesis. In contrast, the activation of protein synthesis was accompanied by changses is the dynamic incorporation of [14C] leucine into the protein at the end of dormancy. The effect of abscisic acid (10(-7) M) on the protein synthesis was not connected with its action of the uptake of labelled precursor and depended on the physiological state of buds and incubation time. A possible mechanism of regulatory effect of abscisic acid on protein synthesis in potato tuber buds is discussed.     

Characterization and Regulation of Protease Synthesis and Activity in Bacillus licheniformis

Extracts of growing and sporulating cells contain a protease activity that has a broad pH optimum and an unusually broad specificity. The activity, which resides in at least two protein fractions, hydrolyzes all peptide bonds and can reduce a mixture of proteins into a mixture of free amino acids with a high efficiency. No inhibitors of the activity were found, but the protease showed a definite preference for denatured protein as substrate. The synthesis of the intracellular protease activity is under catabolite repression control, as is the extracellular activity. However, the synthesis of the two activities is not coordinate, making the relationship between the two unclear. Due to (i) the specificity of the intracellular activity, (ii) the fact that it is synthesized most rapidly under slow or nongrowing conditions, and (iii) our inability to measure in vivo protein turnover in cells containing high levels of enzyme, a scavenger role is postulated for the enzyme. The rate of protein turnover is not a function of the protease content of the cells.     

Light aerobic physical exercise in combination with leucine and/or glutamine-rich diet can improve the body composition and muscle protein metabolism in young tumor-bearing rats

Nutritional supplementation with some amino acids may influence host??s responses and also certain mechanism involved in tumor progression. It is known that exercise influences body weight and muscle composition. Previous findings from our group have shown that leucine has beneficial effects on protein composition in cachectic rat model as the Walker 256 tumor. The main purpose of this study was to analyze the effects of light exercise and leucine and/or glutamine-rich diet in body composition and skeletal muscle protein synthesis and degradation in young tumor-bearing rats. Walker tumor-bearing rats were subjected to light aerobic exercise (swimming 30?min/day) and fed a leucine-rich (3%) and/or glutamine-rich (4%) diet for 10?days and compared to healthy young rats. The carcasses were analyzed as total water and fat body content and lean body mass. The gastrocnemious muscles were isolated and used for determination of total protein synthesis and degradation. The chemical body composition changed with tumor growth, increasing body water and reducing body fat content and total body nitrogen. After tumor growth, the muscle protein metabolism was impaired, showing that the muscle protein synthesis was also reduced and the protein degradation process was increased in the gastrocnemius muscle of exercised rats. Although short-term exercise (10?days) alone did not produce beneficial effects that would reduce tumor damage, host protein metabolism was improved when exercise was combined with a leucine-rich diet. Only total carcass nitrogen and protein were recovered by a glutamine-rich diet. Exercise, in combination with an amino acid-rich diet, in particular, leucine, had effects beyond reducing tumoral weight such as improving protein turnover and carcass nitrogen content in the tumor-bearing host.     

Protein turnover in adipose tissue from fasted or diabetic rats

Protein synthesis and degradation in vitro were compared in epididymal fat pads from animals deprived of food for 48 h or treated 6 or 12 days prior with streptozotocin to induce diabetes. Although both fasting and diabetes led to depressed (-24% to -57%) protein synthesis, the diminution in protein degradation (-63% to -72%) was even greater, so that net in vitro protein balance improved dramatically. Insulin failed to inhibit protein degradation in fat pads of these rats as it does for fed animals. Although insulin stimulated protein synthesis in fat pads of fasted and 12 day diabetic rats, the absolute change was much smaller than that seen in the fed state. The inhibition of protein degradation by leucine also seems to be less in fasted animals, probably because leucine catabolism is slower in fasting. These results show that fasting and diabetes may improve protein balance in adipose tissue but diminish the regulatory effects of insulin.     

Determination of rates of protein synthesis, gain and degradation in intact hind-limb muscle of lambs.

A model of leucine metabolism in the hind-limb muscles of the milk-fed lamb was developed which permitted simultaneous estimation of the rates of protein synthesis (Ks, days-1), degradation (Kd) and therefore gain (Kg) of muscle in vivo. The conclusions drawn from the model were: the rate of protein synthesis in muscle was related to uptake of leucine; the rate of degradation of protein was related to leucine output, as leucine, or its corresponding oxo acid, 4-methyl-2-oxopentanoic acid, or CO2. These findings support findings drawn from a wide range of studies in vitro. There was no correlation between rate of protein synthesis and rate of protein degradation, which suggests that the method can allow independent estimates of each. Estimates of protein synthesis obtained from the model (of leucine metabolism in muscle) were compared with those obtained simultaneously by constant infusion of radioisotope and analysis of incorporation into tissue. There were no significant differences between the mean values obtained for synthesis (Ks), gain (Kg) and degradation (Kd) by either method (Ks 0.051 +/- 0.002, 0.046 +/- 0.007; Kg 0.016 +/- 0.002, 0.004 +/- 0.008; Kd 0.035 +/- 0.004, 0.041 +/- 0.008 day-1, respectively, for tissue analysis and the model). However, Ks obtained from the model was significantly and positively correlated with uptake of leucine from plasma, whereas Ks obtained from tissue analysis was not.