Cell protein degradation in cultured rat embryo fibroblasts suppression by vinblastine of the enhanced proteolysis by serum-deficient media

Rat embryo fibroblasts grown in Eagle's minimal essential medium with 10% serum were labeled with L-[¹⁴C]leucine. After a 24 h cold chase, rates of proteolysis were evaluated by measuring the appearance of trichloroacetic acid-soluble ¹⁴C in the media. Cells remaining in minimal essential medium with 10% serum (basal) showed a proteolysis rate of 1% per h, whereas cells placed in minimal essential medium alone (serum-deficient) showed a stimulation of proteolysis to 3–4% per h. This enhanced proteolysis was transitory, occuring only for the first 4–8 h after cells were placed in the serum-deficient media. Vinblastine 10⁻⁵ M inhibited the enhanced proteolysis 40% but had no effect on basal proteolysis. Control experiments showed no detectable hydrolysis of extracellular proteins, nor did vinblastine affect the rate of protein synthesis. These data suggest that basal and enhanced proteolysis have at least partially distinct mechanisms in the cell and that only enhanced proteolysis involves microtubules.     

Mechanisms of protein degradation in growing and non-growing L-cell cultures.

L-cells prelabelled with [14C]leucine and [3H]thymidine were placed in either fresh growth medium (minimal essential medium with 10% serum) or stepdown medium (minimal essential medium) for 3 days. The 14C/3H ratio remained constant in the growing cultures and decreased in the stationary-phase cultures, indicating no protein turnover in growing cultures and a degradative rate of 0.6%/h in the stationary-phase cultures. Media analysis, however, indicated that 14C-labelled proteins were being degraded at approx. 1.2%/h in growing cultures and 1.7%/h in stationary-phase cultures. Additional studies indicated that a subpopulation of L-cells in the monolayer, comprising approx. 20--30% of the total, were lost in the original processing procedure. Experiments in which recoveries approached 100% by fixation of the monolayer in situ indicated that a protein-degrading subpopulation accounted for all the observed proteolysis in the growing cultures. Proteolysis in these cultures was only partially inhibited with NH4Cl, indicating that only a small part of the protein degradation was occurring in an activated lysosomal-autophagic system. NaF produced a more effective inhibition of proteolysis, but we were not able to distinguish whether this effect was on an ATP-requiring basal-turnover mechanism or a direct effect on unregulated activity of proteinases in the cell hyaloplasm. However, NH4Cl inhibited the proteolysis induced when cells were placed in stepdown medium, suggesting that the induced proteolysis was occurring via the autophagic system. We conclude that L-cells exist in at least two states with respect to protein degradation: (a) a subpopulation that is actively replicating and does not degrade cellular proteins, and (b) a second subpopulation of cells, derived from the preceding one, which degraded most of their labelled proteins, are not capable of further replication, and are not sedimented in an iso-osmotic EDTA buffer solution. In addition, proliferating L-cells, when placed in stepdown medium, begin to degrade cell protein through a mechanism involving autophagolysosomes.     

Energy and calcium ion dependence of proteolysis during sporulation of Bacillus subtilis cells.

Bacterial cells degrade intracellular proteins at elevated rates during starvation and can selectively degrade proteins by energy-dependent processes. Sporulating bacteria can degrade protein with apparent first-order rate constants of over 0.20 h-1. We have shown, with an optimized [14C]leucine-labeling and chasing procedure, in a chemically defined sporulation medium, that intracellular protein degradation in sporulating cells of Bacillus subtilis 168 (trpC2) is apparently energy dependent. Sodium arsenate, sodium azide, carbonyl cyanide m-chlorophenylhydrozone, and N,N'-dicyclohexylcarbodiimide, at levels which did not induce appreciable lysis (less than or equal to 10%) over 10-h periods of sporulation, inhibited intracellular proteolysis by 13 to 93%. Exponentially growing cells acquired arsenate resistance. In contrast to earlier reports, we found that chloramphenicol (100 micrograms/ml) strongly inhibited proteolysis (68%) even when added 6 h into the sporulation process. Restricting the calcium ion concentration (less than 2 microM) in the medium had no effect on rates or extent of vegetative growth, strongly inhibited sporulation (98%), and inhibited rates of proteolysis by 60% or more. Inhibitors of energy metabolism, at the same levels which inhibited proteolysis, did not affect the rate or degree of uptake of Ca2+ by cells, which suggested that the Ca2+ and metabolic energy requirements of proteolysis were independent. Restricting the Ca2+ concentration in the medium reduced by threefold the specific activity in cells of the major intracellular serine proteinase after 12 h of sporulation. Finally, cells of a mutant of B. subtilis bearing an insertionally inactivated gene for the Ca2(+)-dependent intracellular proteinase-1 degraded protein in chemically defined sporulation medium at a rate indistinguishable from that of the wild-type cells for periods of 8 h.     

Serum and insulin inhibit cell death induced by cycloheximide in the human breast cancer cell line MCF-7

Summary Continuous exposure of cells to cycloheximide (CHM) terminates in cell death. This may result from CHM’s inhibition of protein synthesis. In the present study we investigated the effect of serum and insulin on cell death induced by CHM in the human breast cancer cell line MCF-7, and correlated this effect to the inhibition of protein synthesis. Cell death was evaluated by measuring either dead cells by the trypan blue dye exclusion test or by the release of lactic dehydrogenase into the culture medium. CHM (0.1 to 50 μg/ml) was shown to induce cell death in a time- and concentration-dependent manner. Including either fetal bovine serum or insulin in the culture medium inhibited this cell death in a concentration-dependent manner. Protein synthesis as measured by [³H]leucine incorporation was inhibited by the increasing concentration of CHM, However, fetal bovine serum and insulin did not alter the protein synthesis inhibition rate induced by CHM. These results indicate that inhibition of protein synthesis is not enough for cell death to proceed. Insulin or factors present in serum may stabilize some crucial cell proteins (key enzymes, cytoskeletal or membrane components) which are vital for cell life.     

Effect of different protein synthesis inhibitors on the exocrine pancreatocytic autophagocytosis in vivo.

The translational inhibitor cycloheximide is also used as an inhibitor of cellular autophagy and intracellular degradation of endogenous cellular proteins. Some evidence for a similar effect of other inhibitors of protein biosynthesis is also available (largely from in vitro systems). In the present study, the in vivo effects of cycloheximide, emetine and puromycin on autophagy in murine exocrine pancreatic and liver cells were tested using electron microscopic morphometry. The experiments were based on the fact that when the formation of autophagosomes is inhibited, a regression of the autophagolysosomal compartment can be measured, provided intralysosomal degradation in the pre-existing autophagic vacuoles continues at an unchanged rate. To make the measurements easier, autophagolysosomal compartment of the cells was enlarged by administering vinblastine (10 mg/kg b.wt.) for 2 h when the inhibitors were given for an additional 30 min. During this time cycloheximide (0.2 mg/g b.wt.), emetine (0.12 mg/g b.wt.) and puromycin (0.2 mg/g b.wt.), respectively caused 35, 25 and 52% regression of the pancreatocytic autophagolysosomal compartment. Since all the above translational inhibitors inhibited autophagocytosis as well, the possibility of a coupling between the regulation of synthesis and inhibition of proteins arises.     

Control of normal differentiation of myeloid leukemic cells. VI. Inhibition of cell multiplication and the formation of macrophages.

D+ but not D- myeloid leukemic cells can be induced by the appropriate conditioned medium or by serum from endotoxin treated mice, to undergo cell migration in agar, cell attachment to the surface of a Petri dish and differentiation to mature macrophages and granulocytes. Inhibition of cell multiplication by cytosine arabinoside, hydroxyurea, mitomycin C, thymidine, 5-bromodeoxyuridine, 5-iododeoxyuridine, 5-fluorodeoxyuridine or actinomycin D, but not by vinblastine or cycloheximide, induced cell migration, cell attachment to the Petri dish and the formation of macrophages in D+ cells. There was no induction of cell migration or formation of macrophages and a much lower induction of cell attachment in D- cells. The induction of these changes in D+ cells required protein synthesis and the inhibitors showed the same toxicity for D+ and D- cells. The results indicate, that the inhibitors induced specific surface membrane changes in D+ but not in D- cells.     

Infulence of hormones and medium composition on the degradation of phosphoenolpyruvate carboxykinase (GTP) and total protein in Reuber H35 cells.

Reuber H35 cells were pulse-labeled with radioactive leucine and the influence of hormones, serum, and amino acids on protein degradation was investigated during a subsequent chase period. Radioactive, immunoprecipitable phosphoenolpyruvate carboxykinase (GTP) (EC 4.1.1.32) had a half-life of 5 to 6 hours which was not influenced by either N6, O2-dibutyryl adenosine 3':5'-monophosphate, dexamethasone, or insulin. The rate of phosphoenolpyruvate carboxykinase degradation was the same under steady state conditions as during the approach to a new steady state following hormonal induction or deinduction of the enzyme. Therefore, hormonal regulation of enzyme activity in vivo is the result of changes in the rate of enzyme synthesis. The rate of proteolysis for total cell proteins was increased under nutritional step-down conditions produced by the removal of serum or amino acids, or both, from the medium. This effect was completely prevented by insulin. Cycloheximide and puromycin, but not actinomycin D or cordycepin, inhibited protein degradation under step-down conditions but did not further decrease the basal rate of proteolysis measured in the presence of either insulin or serum plus amino acids. There was a good correlation between changes in proteolysis produced by serum and amino acids and changes in the degradation rate of phosphoenolpyruvate carboxykinase. Also, inhibition of proteolysis with cycloheximide and puromycin was accompanied by a decrease in the degradation rate for enzyme antigen. It is suggested that nutritional step-down leads either to the synthesis or activation of a proteolytic system.     

The role of increased proteolysis in the atrophy and arrest of proliferation in serum-deprived fibroblasts

When cultured fibroblasts are deprived of serum, the degradation of long-lived proteins and RNA increases, the cells stop proliferating, and they decrease in size. To determine the role of the increased protein catabolism in these responses, we studied the effects of inhibitors of intralysosomal proteolysis in Balb/c 3T3 cells. When these cells were placed in serum-deficient medium (0.5% serum), the rate of degradation of long-lived proteins increased about twofold within 30 min. This increase was reduced by 50-70% with inhibitors of lysosomal thiol proteases (Ep475 and leupeptin) or agents that raise intralysosomal pH (chloroquine and NH4Cl). By contrast, these compounds had little or no effect on protein degradation in cells growing in 10% serum. Thus, in accord with prior studies, lysosomes appear to be the site of the increased proteolysis after serum deprivation. When 3T3 cells were deprived of serum for 24-48 hours, the rate of protein synthesis and the content of protein and RNA and cell volume decreased two- to fourfold. The protease inhibitor, Ep475, reduced this decrease in the rate of protein synthesis and the loss of cell protein and RNA. Cells deprived of serum and treated with Ep475 for 24-48 hours had about twice the rate of protein synthesis and two- to fourfold higher levels of protein and RNA than control cells deprived of serum. The Ep475-treated cells were also about 30% larger than the untreated cells. Thus, the protease-inhibitor prevented much of the atrophy induced by serum deprivation. The serum-deprived fibroblasts also stopped proliferating and accumulated in the G1 phase of the cell cycle. The cells treated with Ep475 accumulated in G1 in a manner identical to untreated serum-deprived cells. Other agents which inhibited protein breakdown in serum-deprived cells also did not prevent the arrest of cell proliferation. Thus the enhancement of proteolysis during serum deprivation appears necessary for the decrease in size and protein synthesis, but probably not for the cessation of cell proliferation. When cells deprived of serum in the presence or absence of Ep475 were stimulated to proliferate by the readdition of serum, the larger Ep475-treated cells began DNA synthesis 1-2 hours later than the smaller untreated cells. Thus, after treatment with Ep475, the rate of cell cycle transit following serum stimulation was not proportional to the cell's size, protein, or RNA content, or rate of protein synthesis.     

Effects of small molecules on chaperone-mediated autophagy

Autophagy, including macroautophagy (MA), chaperone-mediated autophagy (CMA), crinophagy, pexophagy and microautophagy, are processes by which cells select internal components such as proteins, secretory vesicles, organelles, or foreign bodies, and deliver them to lysosomes for degradation. MA and CMA are activated during conditions of serum withdrawal in cell culture and during short-term and prolonged starvation in organisms, respectively. Although MA and CMA are activated under similar conditions, they are regulated by different mechanisms. We used pulse/chase analysis under conditions in which most intracellular proteolysis is due to CMA to test a variety of compounds for effects on this process. We show that inhibitors of MA such as 3-methyladenine, wortmannin, and LY294002 have no effect on CMA. Protein degradation by MA is sensitive to microtubule inhibitors such as colcemide and vinblastine, but protein degradation by CMA is not. Activators of MA such as rapamycin also have no effect on CMA. We demonstrate that CMA, like MA, is inhibited by protein synthesis inhibitors anisomycin and cycloheximide. CMA is also partially inhibited when the p38 mitogen activated protein kinase is blocked. Finally we demonstrate that the glucose-6-phophate dehydrogenase inhibitor, 6-aminonicotinamide, and heat shock protein of 90 kilodaltons inhibitor, geldanamycin, have the ability to activate CMA.     

Role of the vacuolar apparatus in augmented protein degradation in cultured fibroblasts.

Rat embryo fibroblasts, grown in Eagle's MEM with 10% serum, showed a rapid increase in autophagic vacuoles when placed in MEM with 0-1% serum. Concurrent with this response, degradation of cellular proteins showed a 2-fold increase. We did not find any increases in cathepsin D, beta-glucuronidase, beta-galactosidase, and beta-glucosidase, or proteolytic activity of cell homogenates at pH 3.7 towards endogenous substrates. Homogenates prepared in 250 mM sucrose at pH 7.0 showed a 40% increase in protein breakdown. These data support the hypothesis that the induced increase in proteolysis, characteristic of cells placed in a nutritionally deficient medium, is effected by an activated vacuolar apparatus (lysosomes and autophagic vacuoles). We suggest, however, that this mechanism is distinct from normal protein turnover in the cell, but can be rapidly induced by appropriate alterations in the cellular environment. Finally, this induced proteolytic mechanism is not dependent upon an increase in lysosomal enzymes, but rather a structural alteration within the cell which effects a transfer of cellular proteins into the vacuolar apparatus.     

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.     

Inactivation of protein synthesis stimulating activity in serum by cells

When Ehrlich ascites cells were cultivated in serum-free media their cellular protein synthetic rate declined to a new steady-state level and the cells stopped multiplying. On addition of serum the cellular protein synthetic rate increased to the level before serum starvation and cells resumed multiplication. The activity in serum stimulating protein synthesis was inactivated on incubation with cells. At cell concentrations of the usual culture conditions this inactivation took several hours; at very high cell concentrations it was complete in ten minutes. Serum-starved cells inactivated low serum (2%–6%) media in the same length of time. Studies of inactivation of high serum media demonstrated that cells had a limted capacity to inactivate. Cells grown in 10% serum were unable to inactivate. Inactivation was not due to accumulation in the medium of either low molecular or macromolecular cell products. Inactivation was strongly inhibited at 4° or by treatment of cells with fluoride or cycloheximide (long exposure): less inhibited by treatment with 2-deoxyglucose or glutaraldehyde; and slightly inhibited by treatment with cyanide or cycloheximide (short exposure). Inactivating ability was unaffected by trypsinization. These findings are best explained by the hypothesis that cells take up the serum activity by endocytosis.     

Effects of Small Molecules on Chaperone-Mediated Autophagy

Autophagy, including macroautophagy (MA), chaperone-mediated autophagy (CMA), crinophagy, pexophagy and microautophagy, are processes by which cells select internal components such as proteins, secretory vesicles, organelles, or foreign bodies, and deliver them to lysosomes for degradation. MA and CMA are activated during conditions of serum withdrawal in cell culture and during short-term (MA) and prolonged (CMA) starvation in organisms. Although MA and CMA are activated under similar conditions, they are regulated by different mechanisms. We used pulse/chase analysis under conditions in which most intracellular proteolysis is due to CMA to test a variety of compounds for effects on CMA. We show that inhibitors of MA such as 3-methyladenine, wortmannin, and LY294002 have no effect on CMA. Protein degradation by MA is sensitive to microtubule inhibitors such as colcemide and vinblastine, but protein degradation by CMA is not. Activators of MA such as rapamycin also have no effect on CMA. We demonstrate that CMA, like MA, is inhibited by protein synthesis inhibitors anisomycin and cycloheximide. CMA is also partially inhibited when the P38 mitogen activated protein kinase is blocked. Finally we demonstrate that the glucose-6-phophate dehydrogenase inhibitor, 6-aminonicotinamide, and heat shock protein of 90 kilodaltons inhibitor, geldanamycin, have the ability to activate CMA.     

Macrophage spreading in vitro. III. The effect of metabolic inhibitors, anesthetics and other drugs on spreading induced by subtilisin

The effect of certain drugs on macrophage spreading induced by the proteolytic enzyme sub-tilisin was quantitatively examined and the 50 and 90 % inhibitory concentrations of the drugs were determined. In most instances the viability of the macrophages was preserved, as shown by phagocytic tests and by experiments in which cells pretreated with the drugs and washed were shown to spread when exposed to subtilisin. Inhibitors of electron transport, oxidative phosphorylation or uncouplers at rather small concentrations all effectively blocked macrophage spreading, indicating an ATP requirement. Spreading was also inhibited by neutral or cationic anesthetics and the reciprocal of their 50 % inhibitory concentrations was linearly related to their octanol-water partition coefficients. Inhibition by the anesthetics paralleled their effects on other membrane phenomena, such as nerve conduction, osmotic lysis of erythrocytes, viral induced cell fusion, or Sarcoma I cell to substrate adhesion, also suggesting a membrane target. Spreading was reduced by the anti-inflammatories indomethacin, or phenylbutazone, by high doses of colchicine or vinblastine, by the putative microfilament-acting drug cytochalasin B or by the SH- reagent n-ethyl maleimide. Colchicine and vinblastine effects may involve mechanisms other than their microtubular actions. Several other drugs, including inhibitors of protein synthesis, did not inhibit the spreading of macrophages. Spreading induced by substrate-bound immune complexes was also inhibited by representative metabolic inhibitors or anesthetics.     

Inhibition of cell-substratum attachment of cultured rat heart cells by protein synthesis inhibitors.

Addition of cycloheximide to growth medium of neonatal rat heart cell cultures prevented cell-substratum attachment. Even concentrations of cycloheximide which inhibited only 50% of normal protein synthesis prevented some cells from attaching. Cells which required the longest time to attach were not dependent on protein synthesis. The kinetics of cell-substratum adhesion in the presence of various concentrations of cycloheximide supported the hypothesis that repair of damaged cell membranes was required prior to attachment. An alternate hypothesis that protein synthesis was required for substratum attachment either to synthesize new unique proteins or higher concentrations of existing proteins not damaged by enzymes was not supported by experimentally obtained data. If the second hypothesis were true, no cells would have attached when protein synthesis was completely inhibited (greater than 95%) and all cells should have been equally affected by protein synthesis inhibition; such was not the case. Inhibition of mRNA formation by actinomycin D also should have inhibited attachment completely and this was not observed. Since attachment was minimally affected by actinomycin D, protein synthesis on long-lived mRNA was apparently sufficient for cell-substratum adhesion.     

Effect of transferrin on alkaline phosphatase activity and collagen synthesis in osteoblastic cells derived from newborn mouse calvaria

The effect of transferrin was tested on osteoblastic cells (clone MC3T3-E1) cultured in serum-free medium containing 1% bovine serum albumin (BSA). Transferrin (Tf) stimulated increases of protein content and protein synthesis, but not of DNA content and cell number, in the cells. This protein also increased alkaline phosphatase activity and collagen synthesis in combination with 1% BSA. Actinomycin D and cycloheximide inhibited alkaline phosphatase activity induced by Tf, suggesting that Tf may enhance de novo synthesis of the enzyme. These results indicate that Tf may be involved in differentiation of osteoblastic cells, but not in their proliferation, in vitro.     

Acquired resistance to severe ethanol stress-induced inhibition of proteasomal proteolysis in Saccharomyces cerevisiae

BackgroundAlthough the budding yeast, Saccharomyces cerevisiae, produces ethanol via alcoholic fermentation, high-concentration ethanol is harmful to yeast cells. Severe ethanol stress (> 9% v/v) inhibits protein synthesis and increases the level of intracellular protein aggregates. However, its effect on proteolysis in yeast cells remains largely unknown.MethodsWe examined the effects of ethanol on proteasomal proteolysis in yeast cells through the cycloheximide-chase analysis of short-lived proteins. We also assayed protein degradation in the auxin-inducible degron system and the ubiquitin-independent degradation of Spe1 under ethanol stress conditions.ResultsWe demonstrated that severe ethanol stress strongly inhibited the degradation of the short-lived proteins Rim101 and Gic2. Severe ethanol stress also inhibited protein degradation in the auxin-inducible degron system (Paf1-AID*-6FLAG) and the ubiquitin-independent degradation of Spe1. Proteasomal degradation of these proteins, which was inhibited by severe ethanol stress, resumed rapidly once the ethanol was removed. These results suggested that proteasomal proteolysis in yeast cells is reversibly inhibited by severe ethanol stress. Furthermore, yeast cells pretreated with mild ethanol stress (6% v/v) showed proteasomal proteolysis even with 10% (v/v) ethanol, indicating that yeast cells acquired resistance to proteasome inhibition caused by severe ethanol stress. However, yeast cells failed to acquire sufficient resistance to severe ethanol stress-induced proteasome inhibition when new protein synthesis was blocked with cycloheximide during pretreatment, or when Rpn4 was lost.Conclusions and general significanceOur results provide novel insights into the adverse effects of severe ethanol stress on proteasomal proteolysis and ethanol adaptability in yeast.     

Regulation of the G1 leads to S phase transition in chick embryo fibroblasts with alpha-keto acids and L-alanine.

Temporal inhibition of protein synthesis with cycloheximide prevents subsequent insulin, but not serum-stimulated DNA synthesis in G1-arrested chick embryo fibroblasts (CEF). The inhibition is measured by the incorporation of 3H-thymidine into acid insoluble material and confirmed by chemical estimate of the DNA content of inhibited and uninhibited cells. Cycloheximide treatment is without effect if the cell cultures are maintained at 4 degrees C while exposed to the drug. Several alpha-keto acids (pyruvate, oxaloacetate, alpha-ketobutyrate) at 0.5-1 mM concentrations restore DNA synthesis in previously inhibited cells when combined with insulin. L-alanine (D-alanine is inert) is even more effective than the keto acids in stimulating DNA synthesis after cycloheximide treatment. Glucose transport was unaffected by cycloheximide treatment while lactate levels in medium from inhibited, insulin-stimulated CEF were reduced 70% compared to uninhibited counterparts. We speculate that cycloheximide treatment may lead to the decay of a glycolytic enzyme which compromises the ability of inhibited cells to synthesize pyruvate from glucose, and thus induces an exogenous requirement for alpha-keto acid or L-alanine. A serum component(s) with a molecular weight of about 100 permitted insulin-stimulated DNA synthesis in inhibited cells.