Inhibition of protein synthesis stimulates intracellular protein degradation in growing yeast cells

In exponentially growing cells of Saccharomyces cerevisiae, cycloheximide stimulated intracellular protein degradation to the same extent as did starvation for required amino acids. By using inhibitors of macromolecular synthesis and temperature-sensitive mutants defective in different steps of RNA and protein synthesis it could be demonstrated, that this stimulation of protein degradation was directly related to the inhibition of protein synthesis per se, but not connected to the cessation of ribosomal RNA synthesis or to the inhibition of cell growth.     

Intracellular protein degradation in serum-deprived human fibroblasts.

IMR90 human fibroblasts were labelled by incubation of cells for 48 h in medium containing 10% serum and [3H]leucine. The labelled protein was degraded at a rate of 1%/h during a subsequent incubation in medium with 10% serum. Incubation in medium without serum caused a transient enhancement of the degradation of endogenous protein, which was also found in cells labelled in medium without serum. The degradation of micro-injected haemoglobin was enhanced by serum deprivation in a non-transient manner. These results suggest that enhanced degradation in serum-free medium occurs only for a subpopulation of cell proteins and that it appears transient because the major part of the pool of susceptible endogenous proteins is being degraded during the first 20-30 h in serum-free unlabelled medium. Protein turnover in various cell compartments was measured by a double-labelling technique. Most of the enhanced degradation in serum-deprived cultures (73-83%) was due to breakdown of cytosolic proteins. The enhanced degradation of cytosolic proteins seemed to affect several proteins irrespective of their molecular mass or metabolic stability.     

Lys-bradykinin stimulates Na+ influx and DNA synthesis in cultured human fibroblasts

The effect of Lys-bradykinin on net Na+ influx in serum-deprived cultured human fibroblasts (HSWP cells) was measured. It was found that Lys-bradykinin stimulates net Na+ influx with a K1/2 of 1 nM. When Lys-bradykinin was combined with epidermal growth factor, vasopressin and insulin, the net Na+ influx stimulated was comparable with that measured in response to 10% serum. The above combination of growth factors also was found to stimulate DNA synthesis to 92% of the serum-stimulated levels in HSWP cells and to support cell growth over a period of 6 days. In addition, it was observed that the Na+ influx stimulated by Lys-bradykinin or by the combination of four growth factors was completely inhibited by the amiloride analog benzamil. Thus Lys-bradykinin presumably stimulates the same Na+ transport system as is stimulated by serum. Finally, the present results suggest that an increase in Na+ influx always accompanies DNA synthesis in HSWP cells. On the basis of these observations, it can be hypothesized that Na+ influx is a necessary event to stimulate DNA synthesis.     

Human breast milk stimulates prostaglandin synthesis in cultured human skin fibroblasts

Effect of human breast milk or its fractions on prostaglandin synthesis was investigated in cultured human skin fibroblasts. Prostaglandins released into the media were measured by radioimmunoassay. Incorporation of breast milk (2% level) into 10% fetal calf serum media (for 48 hours) stimulated the synthesis of 6-keto-PGF1 alpha (stable product of prostacyclin) by 800%. This stimulating effect of milk persisted after cold acetone extraction to remove phospholipids and potentiated further after dialysis. Stimulation by one of the commercial formulas (Similac) was less than 50% of the milk effect. Milk also stimulated PGE2 synthesis, although to a much lesser degree. These studies show for the first time that a) human breast milk contains potent factor(s) capable of influencing prostaglandin synthesis and suggest that b) these factors might have a role in the development of lipid synthetic pathways during early life.     

Kinetics of protein degradation in diploid and trisomic human fibroblasts

The degradation rate of long-lived and short-lived proteins was determined in diploid fibroblasts and fibroblasts with trisomy 7 derived from human embryos. Two fractions of proteins were detected in the exponentially growing diploid fibroblasts with half-lives (T 1/2) 37 and 19 hours. The rate of protein degradation increases in diploid fibroblasts as they approach confluence and protein fractions with T 1/2 30, 18 and 12 hours appear. The rate of protein degradation in trisomic fibroblasts does not change for the long-lived and short-lived proteins and is the same in both exponential (T 1/2 31 and 14 hours) and stationary phase (T 1/2 33 and 17 hours). The relative amount of the short-lived proteins in trisomic fibroblasts in the stationary phase decreased as compared with the one in diploid fibroblasts. It is apparent that a mechanism of regulation of protein catabolism in trisomic fibroblasts is impaired.     

Hydrocortisone stimulates fibronectin synthesis in cultured fibroblasts

The effect of hydrocortisone on fibronectin synthesis was investigated in cultured skin fibroblasis. Confluent cells were treated with hydrocortisone (10^?7 M to 10^?5 M) for 2 days and labeled with [³H]proline for 24 h. Fibronectin levels in both the culture medium and the cell layer were studied by gelatin-Sepharose affinity chromatography and SDS-polyacrylamide gel electrophoresis. In control cultures of human fetal skin fibroblasts, fibronectin constituted 8% of the total labeled proteins in the medium. The proportion of fibronectin increased to 13.1% at 10^?7 M hydrocortisone, 15.5% at 10^?6 M and to 19.4% at 10^?5 M. The proportion of fibronectin associated with the cell layer remained at 2-3% of total [³H]prolne-labeled proteins and did not increase with hydrocortisone exposure. The stimulating effect of hydrocortisone on medium fibronectin was also demonstrated in cultured human newborn foreskin fibroblasts and in rabbit skin fibroblasts.     

The effect of canavanine on protein synthesis and protein degradation in IMR-90 fibroblasts

Proteins of IMR-90 fibroblasts incorporating [³⁵S]methionine during a 1 h labelling period in the presence of the arginine analogue canavanine were degraded twice as rapidly in the cells as were proteins similarly made in the presence of arginine. Using both isoelectric focusing and SDS-polyacrylamide gel electrophoretic analyses, the banding patterns of proteins labelled in the presence of canavanine and arginine were found to differ. This banding difference was detected as early as 15 min after canavanine treatment. With the exception of one minor band in isoelectric focusing gel, the relative intensity of labelled protein bands for the control samples remained unchanged during the 2 h period of protein degradation being investigated. This was also true for the proteins labelled in the presence of canavanine, despite the increase in their rate of degradation. Banding difference between canavanine and arginine treatment was also detected in an in vitro reticulocyte lysate translation system dependent on fibroblast mRNA. Proteins labelled in the presence of a different analogue, p-fluorophenylalanine instead of phenylalanine, however, had similar banding patterns as the control both in the lysate system and in intact cells.     

Tumor necrosis factor inhibits collagen and fibronectin synthesis in human dermal fibroblasts

Tumor necrosis factor (TNF) caused inhibition of collagen production by confluent cultures of human dermal fibroblasts in a dose-dependent manner. Concomitant increase of prostaglandin E2 release was observed as a result of TNF-induced cell activation. However, a blockade of the cyclooxygenase pathway of arachidonate metabolism by indomethacin did not abrogate the inhibitory effect of TNF on collagen synthesis, suggesting that this effect could be independent of prostaglandin metabolism. Gel electrophoresis of the newly synthesized macromolecules from the culture media showed that both type I and type III collagens as well as fibronectin were affected by the inhibition. Electrophoresis of cell layer-associated proteins demonstrated that the reduction in amounts of collagen and fibronectin in the medium did not result from an intracellular accumulation of these macromolecules. Production of procollagens was reduced in parallel to that of collagens, suggesting that the effect of TNF is exerted before the processing steps of procollagens. These results clearly show that TNF could play a role in modulation of matrix deposition by fibroblasts during inflammatory processes.     

Ascorbic acid stimulates collagen production without altering intracellular degradation in cultured human skin fibroblasts

The influence of ascorbic acid on intracellular degradation of collagen synthesized by cultured human-skin fibroblasts was examined. In confluent cells maintained in 0.5% serum-supplemented medium, ascorbic acid had no significant effect on collagen degradation measured with hydroxyproline as the marker. Similar results were obtained when collagen degradation was measured with the marker hydroxylysine, the cellular synthesis of which is independent of ascorbic acid. The stimulatory effects of ascorbic acid on collagen production therefore cannot be explained by a change in the rate of degradation. Ascorbic acid acts at some as yet undetermined level to increase the rate of collagen synthesis.     

Electric stimulation of protein and DNA synthesis in human fibroblasts

Human fibroblast cell cultures were employed as a model system to rapidly examine several potentially important variables involved in the use of high-voltage, pulsed galvanic stimulation (HVPGS) to increase the healing rate of soft tissue injuries. Fibroblasts were grown on Millipore filters and exposed to HVPGS of various voltages and pulse rates for 20 min in a rectangular, plastic chamber filled with growth medium. Filters with attached cells were placed either in the center of the chamber or close to the positive or negative electrode. Protein synthesis and DNA synthesis were monitored after stimulation using the radioactively labeled precursors, [3H]proline and [3H]thymidine, respectively. The major results obtained in this study are as follows: 1) the rates of both protein and DNA synthesis can be significantly increased by specific combinations of HVPGS voltage and pulse rate; 2) maximum stimulation of protein and DNA synthesis was obtained at 50 and 75 V, respectively, with a pulse rate of 100 pulses/s and the cells located near the negative electrode; and 3) exposure to HVPGS intensities greater than 250 V (at all pulse rates and locations within the chamber) is inhibitory for both protein and DNA synthesis. In view of the results obtained in preliminary clinical studies on the use of HVPGS for the treatment of dermal ulcers, it appears that similar voltages, pulse rates, and relative electrode location may be required for maximum acceleration of human skin wound healing.     

Regulation of intracellular protein degradation in IMR-90 human diploid fibroblasts

Human diploid fibroblasts (IMR-90) regulate their overall rates of proteolysis in response to the composition of the culture medium and the ambient temperature. The magnitude and, in some cases, the direction of the response depend on the half-lives of the cellular proteins that are radioactively labeled and the time chosen for measurements of protein degradation. Fetal calf serum, insulin, fibroblast growth factor, epidermal growth factor, and amino acids selectively regulate catabolism of long-lived proteins without affecting degradation of short-lived proteins. Fetal calf serum reduces degradative rates of long-lived proteins and is maximally effective at a concentration of 20%, but the effect of serum on proteolysis is evident only for the first 24 hr. Insulin inhibits degradation of long-lived proteins in the presence or absence of glucose and amino acids in the medium, but is maximally effective only at high concentrations (10(-5) M). Amino acid deprivation increases degradative rates of long-lived proteins for the first 6 hr, but then decreases their catabolism for the subsequent 20 hr. Lowered temperature is the only condition tested that significantly alters degradative rates of short-lived proteins. Although cells incubated at 27 degrees C have reduced rates of degradation for both short-lived and long-lived proteins compared to cells at 37 degrees C, lowered temperature reduces catabolism of long-lived proteins to a greater extent.     

Human recombinant gamma-interferon stimulates proliferation and inhibits collagen and fibronectin production by human dental pulp fibroblasts

Human recombinant-gamma-interferon was tested on human dental pulp fibroblast activity in vitro. Fibroblast proliferation was estimated by a colorimetric test. Type I and type III collagens and fibronectin were quantified by radioimmunoassay in culture supernatant from confluent fibroblasts. A dose dependent stimulation of the proliferation was observed when fibroblasts were treated with recombinant-gamma-interferon. In contrast, an inhibition of the synthesis of soluble types I and III collagen and fibronectin by confluent cell cultures treated with recombinant-gamma-interferon occurred without apparent modification of the insoluble collagen level in the cell layer. Quantimetric analysis of type I collagen immunoperoxidase labelling have demonstrated that there was no intracellular storage of type I collagen in these cultured fibroblasts. These data support the view that human recombinant-gamma-interferon can affect human dental pulp fibroblast functions and thus may play an important part in the regulation of fibrosis.     

Alpha-ketoglutarate inhibits glutamine degradation and enhances protein synthesis in intestinal porcine epithelial cells

α-Ketoglutarate (AKG) is a key intermediate in glutamine metabolism. Emerging evidence shows beneficial effects of AKG on clinical and experimental nutrition, particularly with respect to intestinal growth and integrity. However, the underlying mechanisms are unknown. Intestinal porcine epithelial cells (IPEC-1) were used to test the hypothesis that AKG inhibits glutamine degradation and enhances protein synthesis. IPEC-1 cells were cultured for 3 days in Dulbecco's modified Eagle's-F12 Ham medium (DMEM-F12) containing 0, 0.2, 0.5 or 2 mM of AKG. At the end of the 3-day culture, cells were used to determine L-[U-14C]glutamine utilization, protein concentration, protein synthesis, and the total and phosphorylated levels of the mammalian target of the rapamycin (mTOR), ribosomal protein S6 kinase-1 (S6K1) and eukaryotic initiation factor (eIF) 4E-binding protein-1 (4E-BP1). Compared with 0 mM of AKG (control), 0.2 and 0.5 mM of AKG dose-dependently reduced (P<0.05) glutamine degradation and the production of glutamate, alanine and aspartate in IPEC-1 cells. Addition of 0.5 and 2 mM of AKG to culture medium enhanced protein synthesis (P<0.05) by 78 and 101% without affecting protein degradation, compared to the control group. Rapamycin (50 nM; a potent inhibitor of mTOR) attenuated the stimulatory effect of AKG on protein synthesis. Consistent with these metabolic data, the addition of 0.5 or 2 mM of AKG to culture medium increased (P<0.05) the phosphorylated levels of mTOR, S6k1 and 4E-BP1 proteins. Collectively, these results indicate that AKG can spare glutamine and activate the mTOR signaling pathway to stimulate protein synthesis in intestinal epithelial cells.     

Accelerated heme synthesis and degradation in transformed fibroblasts

Various parameters of the heme biosynthetic pathway were studied in two cell lines, one nontransformed and the other malignantly transformed (MLV/MS), both replicating at the same rate. Using the above system enabled us to distinguish between phenomena characteristic of the malignant transformation per se and those due to accelerated growth rate. Heme synthesis and degradation as well as the activities of ALAS, ALAD, PBGD, and FC were found to be increased in the transformed cells. However, the concentration of intracellular heme was markedly reduced from 30.4 +/- 4.4 pmole/mg protein in nontransformed cells to 10.5 +/- 2.6 pmole/mg protein in transformed cells. These observations show that malignant transformation leads to changes in heme metabolism unrelated to growth rate in this cell line.     

Ammonium chloride inhibits basal degradation of newly synthesized collagen in human fetal lung fibroblasts

The objective of this work was to characterize basal degradation of newly synthesized collagen in human fetal lung fibroblasts. Analysis of 22 separate determinations showed that in cells incubated under normal conditions, the level of intracellular degradation was normally distributed with a mean of 15.2% and a standard deviation of 2.6%. Within each experiment, however, the uncertainty (standard deviation) in determining degradation was very small, usually less than 1.5%. Consideration of the large variation between experiments and the ability of our analytic technique to detect small, but "statistically significant," differences between groups within the same experiment led us to formulate two criteria for determining whether degradation measured in cultures exposed to some agent differs in a "biologically significant" way from degradation measured in control cultures. These criteria were used to evaluate the effects of the following proteinase inhibitors on basal degradation: NH4Cl, which increases the pH of subcellular compartments that are normally acidic; and leupeptin and Na-p-tosyl-L-lysine chloromethyl ketone (TLCK), which are inhibitors of lysosomal cathepsins (B and L) that degrade collagen. NH4Cl (16 mM) lowered degradation to an extent that was both statistically and biologically significant, but neither leupeptin nor TLCK affected degradation. The effect of NH4Cl on degradation was independent of its inhibitory effects on production of collagen, protein, and ATP. These results suggest that basal degradation occurs in, or beyond, an acidic (i.e., NH4Cl-sensitive) but nonlysosomal compartment of the cell, and that NH4Cl inhibits processing within, or transport to, that compartment. This is the first report of an agent that inhibits basal degradation of newly synthesized collagen in soft tissue fibroblasts.     

Control of protein synthesis in human fibroblasts by intracellular potassium

Intracellular potassium ion (K⁺) in cultured human fibroblasts (HF cells) was maintained at reduced steady-state levels by incubating cells in various ouabain concentrations. Small decreases in cell K⁺ had no effect on protein synthesis and cell growth, but when cell K⁺ fell below 60–80% of control levels, the rate of protein synthesis decreased in proportion to further reductions in K⁺. DNA synthesis was also inhibited, presumably because of its dependence on protein synthesis. On the other hand, RNA synthesis remained uninhibited over a wide range of K⁺ concentrations, an effect characteristic of many specific inhibitors of protein synthesis.In ouabain-treated cells neither levels of ATP nor transport of amino acids was limiting for protein synthesis. Loss of activity of messenger or other species of RNA was not responsible for inhibition of protein synthesis, since in the presence of actinomycin D, the rate of protein synthesis could be decreased or increased solely by adjusting cell K⁺. Release from ouabain inhibition restored K⁺ levels, macromolecular synthesis, and cell growth, but there was no resulting synchrony of cell division. In cell populations partially synchronized by serum starvation and refeeding protein synthesis was sensitive to reduction in K⁺ levels throughout the cell cycle.Our quantitative results show that cell K⁺ levels, when sufficiently reduced, can determine the rate of protein synthesis and hence the rate of cell growth.     

Increased messenger RNA from protein synthesis inhibited human fibroblasts

Numerous reports have demonstrated that specific protein synthesis in response to specific inducers is markedly stimulated by a simultaneous brief exposure to protein synthesis inhibitors such as cycloheximide. This phenomenon is known as “superinduction” and is most often attributed to the accumulation of cytoplasmic messenger RNA during the inhibition period. Messenger RNA, as defined by rapid labeling, oligo (dt)-cellulose binding, and cell free protein synthesis stimulation was measured in cycloheximide treated human fibroblasts. In spite of a consistent 40% decrease in total polysomal ³H-uridine labeled RNA, a 1.5- to 2-fold increase in extractable mRNA was observed. These data provide direct evidence that protein synthesis inhibition stimulates the appearance of cytoplasmic mRNA and/or completely blocks its degradation and, are consistent with the hypothesis that mRNA accumulation partly underlies the superinduction phenomena.     

Prolyl-tRNA-based rates of protein and collagen synthesis in human lung fibroblasts.

Chondrocyte cultures were established from foetal bovine tracheal cartilage and maintained in Ham's F12 medium with or without 10% (v/v) foetal calf serum. The proteoglycans were isolated and characterized. (1) The proteoglycans from cultures both with and without serum distributed in associative or dissociative CsCl gradients like proteoglycans from cartilage tissue. (2) The amino acid composition, protein contents and glucosamine/galactosamine ratios were grossly identical with those of the tissue derived proteoglycans. (3) Sedimentation coefficients (s⁰) for the monomers were 21.0S and 22.7S from cultures without and with serum respectively. The s⁰ values obtained for aggregates were 72.3S and 93.2S respectively. The limiting viscosity numbers [η] were 248ml/g and 298ml/g respectively. These data corresponded well to those obtained for the tissue-derived proteoglycans. (4) The sizes of the core proteins and chondroitin sulphate chains respectively were the same for both types of cell-culture proteoglycans and similar to those of the tissue proteoglycans. Both the keratan sulphate-rich region and the hyaluronic acid-binding region were identified. The latter, however, was not resistant to limit digestion with trypsin, in contrast with the fragment derived from the bovine nasal cartilage. (5) About 70% of the cell-culture proteoglycans chromatographed in the void volume on a Sepharose 2B column, whereas reduced and alkylated samples (monomers) chromatographed completely included in the column. The two link proteins present in A1 preparations of cartilage proteoglycans were also present in A1 preparations of cell-culture proteoglycans. (6) A minor portion (10%) of the ³⁵S-labelled proteoglycans in the cultures was associated with the cells. Reduced and alkylated samples were larger compared with the monomers in the medium, and chromatographed partly (25%) excluded on the Sepharose 2B column. A larger proportion (50%) of the non-reduced samples chromatographed in the void volume of the column.     

Hyperthermia stimulates energy-proteasome-dependent protein degradation in cultured myotubes

Previous studies suggest that elevated temperature stimulates protein degradation in skeletal muscle, but the intracellular mechanisms are not fully understood. We tested the role of different proteolytic pathways in temperature-dependent degradation of long- and short-lived proteins in cultured L6 myotubes. When cells were cultured at different temperatures from 37 to 43 degrees C, the degradation of both classes of proteins increased, with a maximal effect noted at 41 degrees C. The effect of high temperature was more pronounced on long-lived than on short-lived protein degradation. By using blockers of individual proteolytic pathways, we found evidence that the increased degradation of both long-lived and short-lived proteins at high temperature was independent of lysosomal and calcium-mediated mechanisms but reflected energy-proteasome-dependent degradation. mRNA levels for enzymes and other components of different proteolytic pathways were not influenced by high temperature. The results suggest that hyperthermia stimulates the degradation of muscle proteins and that this effect of temperature is regulated by similar mechanisms for short- and long-lived proteins. Elevated temperature may contribute to the catabolic response in skeletal muscle typically seen in sepsis and severe infection.