Leucine in cultured cells: its metabolism and use as a marker for protein turnover

Seasonal variations in the metabolomic profile of the ovarian follicle components in Italian Mediterranean Buffaloes

The aim of this work was to evaluate the seasonal effect on the metabolomic profile of the ovarian follicle in Italian Mediterranean buffalo to unravel the causes of the reduced competence during the non-breeding season (NBS). Samples of follicular fluid, follicular cells, cumulus cells and oocytes were collected from abattoir-derived ovaries during breeding season (BS) and NBS and analyzed by 1H Nuclear Magnetic Resonance. The Orthogonal Projections to Latent Structures of the Discriminant Analysis showed clear separation into seasonal classes and Variable Importance in Projection method identified differentially abundant metabolites between seasons. Seasonal differences were recorded in metabolite content in all analyzed components suggesting that the decreased oocyte competence during NBS may be linked to alteration of several metabolic pathways. The pathway enrichment analysis revealed that differences in the metabolites between the seasons were linked to glutathione, energy generating and amino acid metabolism and phospholipid biosynthesis. The current work allows the identification of potential positive competence markers in the follicular fluid as glutathione, glutamate, lactate and choline, and negative markers like leucine, isoleucine and β-hydroxybutyrate. These results form a major basis to develop potential strategies to optimize the follicular environment and the IVM medium to improve the competence of oocytes during the NBS.

Leucine retention in lysosomes is regulated by starvation

Cells can respond to starvation by up-regulating stress responses that promote the recycling or scavenging of essential nutrients. We identify a starvation response that allows cells to store the essential amino acid leucine within lysosomes when extracellular amino acids are scarce. This “storage” response allows cells to sequester an essential amino acid in support of protein synthesis. We find that numerous essential amino acids are trafficked through lysosomes even when extracellular concentrations are high, suggesting that constitutive flux through lysosomes is related to starvation-induced storage.

Cells acquire essential nutrients from the environment and utilize adaptive mechanisms to survive when nutrients are scarce. How nutrients are trafficked and compartmentalized within cells and whether they are stored in response to stress remain poorly understood. Here, we investigate amino acid trafficking and uncover evidence for the lysosomal transit of numerous essential amino acids. We find that starvation induces the lysosomal retention of leucine in a manner requiring RAG-GTPases and the lysosomal protein complex Ragulator, but that this process occurs independently of mechanistic target of rapamycin complex 1 activity. We further find that stored leucine is utilized in protein synthesis and that inhibition of protein synthesis releases lysosomal stores. These findings identify a regulated starvation response that involves the lysosomal storage of leucine.

The role of the extracellular matrix in articular chondrocyte regulation

The in vivo role of the extracellular matrix and the manner in which it interfaces with soluble regulators remains largely unknown. The current study reports the extracellular Type II collagen modulation of transforming growth factor-beta 1-stimulated proliferation, proteoglycan synthesis, messenger ribonucleic acid expression for transforming growth factor-beta 1, and integrin messenger ribonucleic acid expression in articular chondrocytes from adults. This study shows that this cytokine modulation occurs through a mechanism initiated by the attachment of Type II collagen to the beta1-integrin. Transforming growth factor-beta 1 stimulated deoxyribonucleic acid and proteoglycan synthesis in a bimodal fashion. Extracellular Type II collagen increased transforming growth factor-beta 1-stimulated deoxyribonucleic acid and proteoglycan synthesis, aggrecan gene expression as much as 400%, and alpha1(II) procollagen gene expression as much as 180% in a dose-dependent fashion. Heat inactivation of the Type II collagen abrogated the observed effects on deoxyribonucleic acid and proteoglycan synthesis. In contrast to Type II collagen, heat-denatured collagen and bovine serum albumin showed none of the observed effects. The presence of Type II collagen in the alginate bead cultures was found to diminish the messenger ribonucleic acid expression for alpha2 integrin and alter the cellular distribution pattern of the beta1 integrin receptors. Blocking of the beta1-integrin with cyclic-peptides containing the Arg-Gly-Asp sequences and antibodies reduced chondrocyte attachment to Type II collagen by 93%. The physiologic effects shown by the chondrocyte as a result of blocking this attachment to Type II collagen were a significant reduction in transforming growth factor-beta 1-stimulated deoxyribonucleic acid and proteoglycan synthesis. The conclusions elucidate the role played by the extracellular matrix in cytokine-specific regulation of the articular chondrocyte. The authors have shown that extracellular Type II collagen acts through a beta1-integrin mediated mechanism to modulate the chondrocyte response to transforming growth factor-beta 1.

Single amino acid (arginine) deprivation: rapid and selective death of cultured transformed and malignant cells

The effects of arginine deprivation (-Arg) has been examined in 26 cell lines. Less than 10% of those with transformed or malignant phenotype survived for > 5 days, and many died more rapidly, notably leukaemic cells. Bivariate flow cytometry confirmed that vulnerable cell lines failed to move out of cell cycle into a quiescent state (G0), but reinitiated DNA synthesis. Many cells remained in S-phase, and/or had difficulty progressing through to G2 and M. Two tumour lines proved relatively 'resistant', A549 and MCF7. Although considerable cell loss occurred initially, both lines showed a 'cell cycle freeze', in which cells survived for > 10 days. These cells recovered their proliferative activity in +Arg medium, but behaved in the same manner to a second -Arg episode as they did to the first episode. In contrast, normal cells entered G0 and survived in -Arg medium for several weeks, with the majority of cells recovering with predictable kinetics in +Arg medium. In general, cells from a wide range of tumours and established lines die quickly in vitro following -Arg treatment, because of defective cell cycle checkpoint stringency, the efficacy of the treatment being most clearly demonstrated in co-cultures in which only the normal cells survived. The findings demonstrate a potentially simple, effective and non-genotoxic strategy for the treatment of a wide range of cancers.

Human recombinant interleukin-1 beta- and tumor necrosis factor alpha-mediated suppression of heparin-like compounds on cultured porcine aortic endothelial cells

Cytokines are known to tip the balance of the coagulant-anticoagulant molecules on the endothelial cell surface toward intravascular coagulation. Their effects on endothelial cell surface-associated heparin-like compounds have not been examined yet. Incorporation of [35S]sulfate into heparan sulfate on cultured porcine aortic endothelial cells was suppressed by human recombinant interleukin-1 beta (rIL-1 beta) or tumor necrosis factor alpha (rTNF alpha) in a dose- and time-dependent manner with little effect on cell number, protein content, and [3H]leucine incorporation of cells. Maximal inhibition was achieved by incubation of cells with 100 ng/ml of rIL-1 beta or 5 ng/ml of rTNF alpha for 12-24 hours, resulting in a reduction of the synthesis of heparan sulfate on the cell surface by approximately 50%. The dose dependency was consistent with that seen in the stimulation of endothelial cell procoagulant activity by each cytokine. The suppression of heparan sulfate synthesis was sustained for at least 48 hours after pretreatment of cells with cytokines and was unchanged after the addition of indomethacin or polymyxin B. The rate of degradation of prelabeled 35S-heparan sulfate on the cell surface was not altered by cytokine treatments. Neither the size, the net negative charge, nor the proportion of the molecule with high affinity for antithrombin III of endothelial cell heparan sulfate was changed by cytokines. Furthermore, specific binding of 125I-labeled antithrombin III to the endothelial cell surface was reduced to 40-60% of control by cytokines. In parallel with reduction in binding, antithrombin III cofactor (heparin-like) activity was partially diminished in cytokine-treated endothelial cells. Thus, cytokine-mediated suppression of heparin-like substance on endothelial cells appears to be another cytokine-inducible endothelial effects affecting coagulation.

Differential degradation of intracellular proteins in human skin fibroblasts of mitotic and mitomycin-C (MMC)-induced postmitotic differentiation states in vitro

Rates of degradation of short- and long-lived proteins were analysed in homogeneous fibroblast cultures of mitotic or mitomycin C (MMC)-induced postmitotic states. When the highly mitotic MFII type cells--the major cell type of so called "early passage" or "young" fibroblasts--differentiate into MFIII type cells, the last mitotic fibroblast type, and further into MMC-induced postmitotic fibroblasts, the degradation of short-lived proteins increases by a factor of 1.4, resulting in significantly reduced half-lives of these proteins in the postmitotic fibroblasts. From the highly mitotic MFII to the final postmitotic PMFVI-type cells via the intermediates MFIII, PMFIV and PMFV, the half lives (t1/2) of short-lived proteins decrease by a total of 122 min in average, from 362 to 240 min. Degradation of long-lived proteins did not change significantly from cell type MFII to PMFVI. As analysed by two-dimensional (2D)-gel electrophoresis the half-lives of the mitotic and postmitotic cell-type-specific proteins except one, protein PIVa (33 kDa; Pi 5.0), range between 33.2 h and 62.9 h. Protein PIVa, the first protein specific for postmitotic cells, is initially expressed 18 h after the induction of the postmitotic state by mitomycin C (MMC) and has a half-life of approximately 66 min. This may indicate that protein PIVa could function as one possible regulatory factor controlling the postmitotic differentiation state.

Stimulation of proteoglycans by IGF I and II in microvessel and large vessel endothelial cells

Endothelial cells were cultured from bovine capillaries and pulmonary arteries, and the effect of insulinlike growth factor (IGF) I and II (multiplication-stimulating activity) and insulin on the synthesis of proteoglycans was determined. IGF I and II stimulated 35SO4 incorporation into proteoglycans in a dose-dependent manner in both microvessel and pulmonary artery endothelial cells with maximum threefold increases. In pulmonary artery cells, the IGFs caused a general stimulation of all classes of glycosaminoglycan-containing proteoglycans. In microvessel endothelial cells, the IGFs appeared to preferentially increase heparan sulfate-containing proteoglycans. Insulin, at concentrations up to 10(-6) M, had no effect on the synthesis of proteoglycans in either microvessel or pulmonary arterial endothelial cells. Thus, the IGFs stimulate the synthesis of proteoglycans in both microvessel and large vessel endothelial cells, a property that is not mimicked by insulin. Because vascular endothelial cells are bathed by IGFs in vivo, such IGF-mediated functions are likely to be significant in both the normal physiology of vascular endothelium and in disease states such as diabetes mellitus.

Immediate effects of serum depletion on dissociation between growth in size and cell division in proliferating 3T3 cells

Proliferating nonconfluent 3T3 cells become committed to proceed through the cell cycle or to enter G0 during the first post-mitotic part of G1 (G1pm). The decision to proceed through G1pm is dependent on the presence of serum growth factors in the culture medium. Cells that have passed this particular growth-factor-dependent cell cycle stage are independent of serum growth factors and undergo mitosis on schedule. We report here that G1ps, S, and G2 cells cease to increase in size when serum is withdrawn. As a result the mitotic cell size after 8 hours serum starvation is reduced to approximately 60% of the normal mitotic cell. This reduced growth in cell size is due to a rapid decrease in protein synthesis and some increase in protein degradation. This dissociation between growth in size and cell-cycle progression within a single cell cycle provides a new approach to study the two processes separately.

Kinetic analysis of regulatory events in G1 leading to proliferation or quiescence of Swiss 3T3 cells

Kinetic analysis of cellular response to serum deprivation or inhibition of protein synthesis was performed on Swiss 3T3 cells. Time-lapse cinematographic analysis of individual cells transiently exposed to serum-free medium (with or without the addition of purified growth factors) or cycloheximide enabled a detailed mapping of the magnitude and variability of cellular response in different parts of the cell cycle. In all cells, in all stages of the cell cycle, serum deprivation resulted in inhibition of protein synthesis, but only in postmitotic cells in the first 3-4 hr of G1 (here denoted the G1pm phase) did it produce cell-cycle arrest. During G1pm, the cells are highly dependent on the continuous presence of serum growth factors and a high level of protein synthesis in order to progress toward mitosis. A 1-hr exposure to serum-free medium or to cycloheximide was sufficient to force most G1pm cells into a state of quiescence (G0), from which the cells required 8 hr to return to G1pm. During G1pm the cells complete the growth factor-dependent processes leading to commitment for proliferation. Thereafter they enter the growth factor-independent pre-DNA-synthetic part of G1 (here denoted G1ps). The commitment process in G1pm could be successfully completed in the presence of platelet-derived growth factor as the only supplied growth factor. Epidermal growth factor and insulin were insufficient for the completion of the commitment processes in G1pm, although they were able to temporarily prevent the G1pm cells from entering G0 during serum starvation. Under conditions optimal for proliferation, the cells complete the commitment processes in G1pm within a remarkably constant time period. Almost all cells in the population left G1pm and entered G1ps between the third and fourth hour after mitosis. The duration of G1ps, on the other hand, showed a large intercellular variability consistent with a transition-probability event. In fact, G1ps accounts for most of the variability in G1 and cell cycle time.

Reduced autophagic activity, improved protein balance and enhanced in vitro survival of hepatocytes isolated from carcinogen-treated rats

Sequential carcinogen treatment (diethylnitrosamine/partial hepatectomy followed by 2-acetylaminofluorene (2-AAF] induced multiple hepatocarcinomas in rats with 100% certainty within a year. Enzyme-altered lesions, i.e. gamma-glutamyltranspeptidase (GGT)-positive and/or ATPase-negative cell foci, were numerous already at 8 weeks, and suspensions of purified hepatocytes isolated (by collagenase perfusion) at this time contained 30-40% GGT-positive cells. These hepatocyte suspensions were markedly deficient with respect to autophagic protein degradation (in comparison with cell suspensions from normal rats), and the cells lost less protein and survived much better than normal hepatocytes in culture under conditions of amino acid deprivation (which activates the autophagic mechanism). The anabolic advantage of reduced autophagy may possibly contribute to the selective outgrowth of preneoplastic cells during the earliest stage of liver carcinogenesis. Inclusion of the autophagy inhibitor 3-methyladenine in the culture medium elevated the survival of normal hepatocytes up to the level seen with hepatocytes from carcinogen-treated animals, suggesting that protection of normal cells by autophagy suppression may be a potentially interesting therapeutic principle.

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.

Altered degradation of intracellular proteins in aging human fibroblasts

Confluent cultures of fibroblasts at different population doubling levels were incubated with [14C]leucine for 2 days and with [3H]leucine for 2 h to label long-lived and short-lived proteins, respectively. Proteolysis was then measured in the presence of excess unlabeled leucine to prevent reutilization of the isotope. Catabolism of long-lived proteins was reduced in senescent cells when measured in media without fetal bovine serum, insulin, fibroblast growth factor, or dexamethasone. In contrast, degradation of short-lived proteins was increased in senescent cells but only when measured in the presence of serum, hormones, and growth factors. Further experiments with cells of varying ages indicate that in unsupplemented medium half-lives of long-lived proteins lengthened by as much as 20 min per population doubling and in supplemented media half-lives of short-lived proteins decreased by 4 min per population doubling. The reduced catabolism of long-lived proteins in senescent cells cannot be explained by age-related changes in protein secretion or cell death during degradation measurements. These alterations in proteolysis may have major effects on protein content and composition in senescent cells.

Protein degradation in 3T3 cells and tumorigenic transformed 3T3 cells

To study the relation of overall rates of protein degradation in the control of cell growth, we determined if transformation of fibroblasts to tumorigenicity affected their rates of degradation of short- and long-lived proteins. Rates of protein degradation were measured in nontumorigenic mouse Balb/c 3T3 fibroblasts, and in tumorigenic 3T3 cells transformed by different agents. Growing 3T3 cells, and cells transformed with Moloney sarcoma virus (MA-3T3) or Rous sarcoma virus (RS-3T3), degraded short- and long-lived proteins at similar rates. Simian virus 40 (SV-3T3)- and benzo(a)pyrene (BP-3T3)-transformed cells had slightly lower rates of degradation of both short- and long-lived proteins. Reducing the serum concentration in the culture medium from 10% to 0.5%, immediately caused about a twofold increase in the rate of degradation of long-lived proteins in 3T3 cells. Transformed lines increased their rates of degradation of long-lived proteins only by different amounts upon serum deprivation, but none of them to the same extent as did 3T3. Greater differences in the degradation rates of proteins were seen among the transformed cells than between 3T3 cells and some transformed cells. Thus, there was no consistent change in any rate of protein degradation in 3T3 cells due to transformation to tumorigenicity.

The effect of phenobarbital on protein metabolism of liver. Results with isolated hepatocytes

A technique has been devised which makes use of an amino acid alternatively labeled with either [14C] or [3H], and permits the simultaneous evaluation of synthesis, catabolism and secretion by the same sample of isolated rat liver cells during the same time-period of incubation. This technique has been used to study protein metabolism of liver cells isolated from rats treated with 4 doses of phenobarbital (8 mg/100 g body weight) given in the 4 days before killing the animals. Total protein synthesis and secretion do not change in phenobarbital-treated rats; albumin represents 40% of secreted protein in both normal and treated rats. On the contrary, the parameters which indicate protein degradation are lower in phenobarbital-treated than in normal rats, showing that protein catabolism is appreciably reduced in the liver cells obtained from rats treated with phenobarbital.

Characteristics of amino acid metabolism by isolated alveolar type II cells

Alveolar type II cells of the lung are important in producing the lipoprotein surfactant. Most studies about metabolism in type II cells have focussed on lipid precursors for phospholipid metabolism. Surfactant contains a unique apoprotein; yet relatively little is known about the metabolism of amino acids by type II cells. Type II cells were isolated using density gradient centrifugation followed by centrifugal elutriation. Alanine (Ala), leucine (Leu), valine (Val), and phenylalanine (Phe) incorporation into protein and lipid and oxidation to CO2 was measured after the cells were incubated for 2 h. For alanine metabolism, 22% of total radioactivity from alanine was incorporated into protein, 20% into lipid, and 58% oxidized to CO2. For leucine, 51% was incorporated into protein, 23% into lipid, and 22% oxidized to CO2. Fifty percent of radioactivity from valine metabolism was incorporated into protein, 5% into lipid, and 47% oxidized to CO2. Virtually all (95%) of phenylalanine, however, was utilized for protein synthesis only. Puromycin and cycloheximide decreased protein synthesis from Ala, Leu, and Phe but had little affect on Ala and Leu metabolism to lipid or CO2. The hypolipidemic drug clofibrate inhibited all aspects of amino acid metabolism. In summary, type II cell amino acid metabolism is regulated similar to that of cells from skeletal muscle and adipose tissue, but in contrast to hepatocytes, type II cells readily oxidize valine and utilize leucine for lipid as well as protein synthesis.

Leucine metabolism as a source of acetate in the synthesis of hyaluronic acid

Synovial fibroblasts were incubated in nutrient medium with either L-[U-14C]leucine or L-[4,5-3H]leucine to reveal peptides associated with hyaluronic acid. Isotope was found in hyaluronic acid extracted from culture medium by repeated density gradient ultracentrifugation, but 76-98% of the labelled hyaluronic acid fraction was recovered as oligosaccharide by Sephadex G-25 gel chromatography after digestion with protease-free staphylococcal hyaluronidase (EC 4.2.99.1). Radioactivity in acid digests of the oligosaccharide fractions (i) was volatile, (ii) separated similarly to acetate in Biogel P2 chromatography, and (iii) was identified as acetate by melting point after conjugation as a p-phenylphenacyl ester crystallized to constant specific activity. The synovial fibroblast thus possesses metabolic pathways for complete transformation of leucine to acetylCoA, which operate freely in adequate nutrient medium and are a significant source of acetyl groups in hyaluronic acid synthesis.

Protein turnover and proliferation. Turnover kinetics associated with the elevation of 3T3-cell acid-proteinase activity and cessation of net protein gain

1. At least 95% of the total protein of A31-3T3 cell cultures undergoes turnover. 2. First-order exponential kinetics were used to provide a crude approximation of averaged protein synthesis, Ks, degradation, Kd, and net accumulation, Ka, as cells ceased growth at near-confluent density in unchanged Dulbecco's medium containing 10% serum. The values of the relationship Ka = Ks - Kd were : 5%/h = 6%/h - 1%/h in growing cells, and 0%/h = 3%/h - 3%/h in steady-state resting cells. 3. As determined by comparison of the progress of protein synthesis and net protein accumulation, the time course of increase in protein degradation coincided with the onset of an increase in lysosomal proteinase activity and decrease in thymidine incorporation after approx. 2 days of exponential growth. 4. After acute serum deprivation, rapid increases in protein degradation of less than 1%/h could be superimposed on the prevailing degradation rate in either growing or resting cells. The results indicate that two proteolytic mechanisms can be distinguished on the basis of the kinetics of their alterations. A slow mechanism changes in relation to proliferative status and lysosomal enzyme elevation. A prompt mechanism, previously described by others, changes before changes in cell-cycle distribution or lysosomal proteinase activity. 5. When the serum concentration of growing cultures was decreased to 1% or 0.25%, then cessation of growth was accompanied by a lower steady-state protein turnover rate of 2.0%/h or 1.5%/h respectively. When growth ceased under conditions of overcrowded cultures, or severe nutrient insufficiency, protein turnover did not attain a final steady state, but declined continually into the death of the culture.

Defective ornithine metabolism in cultured skin fibroblasts from patients with the syndrome of hyperornithinemia, hyperammonemia and homocitrullinuria

The syndrome of hyperornithinemia, hyperammonemia, and homocitrullinuria (HHH) is a metabolic disorder resulting in protein intolerance and mental retardation. The primary metabolic defect has yet to be determined. We studied some aspects of ornithine metabolism in cultured skin fibroblasts from two patients from two patients with the HHH syndrome. The fibroblasts failed to incorporate 14C-label from ornithine into protein, a defect also observed in fibroblasts from patients with gyrate atrophy of the choroid and retina and a deficiency of ornithine aminotransferase activity. The defect can be corrected in heterokaryons formed between these two types of fibroblasts. These findings indicate that fibroblasts are suitable for further studying the underlying metabolic defect in HHH syndrome. The combination of the ornithine incorporation assay and genetic complementation analysis provide a confirmatory test for the diagnosis of this syndrome.

Degradation of proteins microinjected into IMR-90 human diploid fibroblasts

Erythrocyte ghosts loaded with 125I-labeled proteins were fused with confluent monolayers of IMR-90 fibroblasts using polyethylene glycol. Erythrocyte-mediated microinjection of 125I-proteins did not seriously perturb the metabolism of the recipient fibroblasts as assessed by measurements of rates of protein synthesis, rates of protein degradation, or rates of cellular growth after addition of fresh serum. A mixture of cytosolic proteins was degraded after microinjection according to expected characteristics established for catabolism of endogenous cytosolic proteins. Furthermore, withdrawal of serum, insulin, fibroblast growth factor, and dexamethasone from the culture medium increased the degradative rates of microinjected cytosolic proteins, and catabolism of long-lived proteins was preferentially enhanced with little or no effect on degradation of short-lived proteins. Six specific polypeptides were degraded after microinjection with markedly different half-lives ranging from 20 to 320 h. Degradative rates of certain purified proteins (but not others) were also increased in the absence of serum, insulin, fibroblast growth factor, and dexamethasone. The results suggest that erythrocyte-mediated microinjection is a valid approach for analysis of intracellular protein degradation. However, one potential limitation is that some microinjected proteins are structurally altered by the procedures required for labeling proteins to high specific radioactivities. Of the four purified proteins examined in this regard, only ribonuclease A consistently showed unaltered enzymatic activity and unaltered susceptibility to proteolytic attack in vitro after iodination.

Effect of serum step-down on protein metabolism and proliferation kinetics of NHIK 3025 cells

Human NHIK 3025 cells growing exponentially in 30% or 3% serum had population doubling times of 19.1 and 27.6 hours, respectively. These values were equal to the calculated protein doubling times (17.6 and 26.5 hours, respectively), showing that the cells were in balanced growth at both serum concentrations. Stepdown from 30% to 3% serum reduced the rate of protein synthesis within 1--2 hours, from 5.7%/hour to 4.3%/hour, while the rate of protein degradation was unchanged (1.7%/hour). In cells synchronized by mitotic selection from an exponentially growing population, the median cell cycle durations in 30% and 3% serum were 17.2 and 23.6 hours, respectively, which were also in good agreement with the protein doubling times. The median G1 durations were 7.1 and 9.6 hours, respectively. Thus the duration of G1 relative to the total cell cycle duration was the same in the two cases. Complete removal of serum for a period of 3 hours resulted in a 3-hour prolongation of the cell cycle regardless of the time after mitotic selection at which the serum was removed. For synchronized cells, the rate of entry into both the S phase and into the subsequent cell cycle were reduced in 3% serum as compared to 30% serum, the former rate being significantly greater than the latter at both serum concentrations. Our results thus indicate that these cells are continuously dependent upon serum throughout the entire cell cycle.

Protein degradation in skin fibroblasts from patients with Duchenne muscular dystrophy

The rates of degradation of [3H]leucine-labelled proteins have been measured in cultures of skin fibroblasts obtained from normal controls (five subjects) and patients with Duchenne muscular dystrophy (six subjects). Cultures were incubated with [3H]leucine (10 microCi/ml) for 60 min to label "short-lived" proteins, and with [3H]leucine (5 microCi/ml) for 60 h to label "long-lived" proteins. Optimal wash procedures were devised for removal of [3H]leucine from the extracellular space and from cell pools before beginning degradation measurements. Re-utilization of [3H]leucine released from degraded labelled proteins was prevented by supplementing the medium with 4mM-leucine. Rates of degradation did not depend on the growth state of the cells or on cell age over the range used (passages eight-20). Degradation of long-lived proteins was approximately linear over a 24h period, at a rate of 1.0% per h. 30% of short-lived protein was degraded within 6h. No differences were observed between protein degradation in normal fibroblasts and in those from patients with Duchenne muscular dystrophy.

Protein synthesis and degradation in growth regulation in rat embryo fibroblasts: role of fast-turnover and slow-turnover protein

Cultured rat embryo fibroblasts, when stimulated to grow by the addition of fresh medium containing 10% serum, showed an increase in synthesis of slow-turnover proteins while maintaining a uniform degradation rate for these proteins. Slow-turnover proteins with a half-life of 2.4 days accounted for approximately 95% of the cell protein, while the remaining protein could be described in terms of two fast-turnover pools. When we labeled cells to limiting levels over a period of 4 days, the fast-turnover pools became undetectable; with 2-hour labeling periods, however, 25% of the label entered the fast-turnover pools. Fibroblasts, stimulated to grow by fresh growth medium, showed proportionate and coordinate increases in synthesis of both fast-turnover and slow-turnover proteins during the growth period, both returning to baseline levels on reaching the new steady state. No changes could be detected in degradation of either pool during growth. Fibroblasts placed in a serum-free medium showed a decrease in cellular protein and an increased degradation of slow-turnover proteins, while degradation of fast-turnover proteins remained unchanged. We conclude that the slow-turnover protein pool forms the bulk of the cell proteins and turns over at a fairly constant rate. Growth stimulation is effected almost entirely by stimulation of protein synthesis in this pool, while decreasing cellular protein growth is a result of enhanced degradation within this pool.

Turnover of proteins in asporogenic Bacillus megaterium. Evidence for a gradual decrease of the turnover rate

The rate of protein turnover in asporogenic Bacillus megaterium decreases continuously during incubation in a sporulation medium. The capability of equilibration of external amino acids with amino acids in the metabolic pool of non-growing cells was retained for at least 5 h. Leucine, while repressing the synthesis of the exocellular protease, does not significantly influence the course of protein degradation in vivo. Transfer of non-growing cells after 4 h to a fresh sporulation medium does not influence the rate of protein degradation. The gradual decrease of the rate of protein turnover in non-growing cells of the asporogenic variant is thus not an artifact caused by a decreased uptake of amino acids by cells or by conditions under which the protein turnover is determined.

The effect of protease inhibitors and decreased temperature on the degradation of different classes of proteins in cultured hepatocytes

Leupeptin, chymostatin and antipain inhibited the degradation of long-lived proteins in cultured rat hepatocytes by 20-30%, probably by inhibiting lysosomal proteases: (1) Leupeptin and chymostatin decreased to a similar extent the degradation of an exogenous protein 125I-asialo fetuin, a process known to occur within lysosomes. (2) In extracts of cells treated with leupeptin, cathepsin B activity was inhibited by 35-50%. (3) Leupeptin, chymostatin and antipain inhibited proteolysis by homogenates of liver lysosomes but not by the supernatant fraction. These agents, however, do not appear to rapidly permeate the membrane of isolated lysosomes. Leupeptin, chymostatin and antipain did not inhibit the breakdown of short-lived normal cell proteins, and ones containing amino acid analogs. Even when the amount of abnormal proteins was increased, such that it comprised a large fraction of cell protein, the degradation of these polypeptides was still very rapid and not affected by these inhibitors. The pathway for the degradation of short-lived cell proteins thus appears distinct from that responsible for degradation of long-lived cell proteins. In accord with this conclusion, reduction of the temperature of cultures inhibited the breakdown of long-lived proteins to a much greater extent than it affected the breakdown of short-lived ones. Treatment of cultured hepatocytes with glucagon, or deprivation for serum or amino acids stimulated the degradation of the more stable cell proteins but did not affect the breakdown of 125I-asialo-fetuin. Under these conditions leupeptin and chymostatin inhibited the breakdown of long-lived cell proteins to the same extent as in control cultures. Thus, lysosomal enzymes seem to play an important role in protein breakdown both in fed hepatocytes and in cells where proteolysis is accelerated.

The effect of amino acids on the temperature sensitive phenotype of the mammalian leucyl-tRNA synthetase mutant tsHl and its revertants

The temperature sensitive leucyl-tRNA synthetase mutant tsHl and two revertants have been compared to the parental Chinese hamster ovary cells with respect to the effects of amino acid concentrations in the medium on growth. Elevating the leucine concentration 30- or 100-fold allowed tsHl to grow exponentially at 38.5 degrees C, normally the nonpermissive temperature. Partial revertants that had recovered some enzyme activity required smaller supplements for growth. Measurements of the leucine pools indicated that they respond directly to the extracellular leucine concentration and may mediate the effect. Use of combinations of amino acids confirmed that isoleucine has a similar though weaker effect on tsHl and identified an even weaker protection by valine. The triple combination of leucine, isoleucine and valine was a much more efficient medium supplement and three times normal concentrations of these amino acids supported growth of tsHl at 38.5 degrees C. It is postulated that they are acting at their respective aminoacyl-tRNA synthetases to help stabilize a complex which also contains the mutant leucyl-tRNA synthetase. The pool size measurements also showed that the leucine pools of tsHl and a revertant increased 2-fold more in a response to increased temperature than those of WT. It is suggested that this is a regulatory response to low leucyl-tRNA synthetase activity and is important in determining growth phenotypes.

Transformation-sensitive cell surface protein: isolation, characterization, and role in cellular morphology and adhesion

Cell surface protein is the major cell surface glycoprotein of chick embryo fibroblasts. We have isolated and purified this glycoprotein and find that it is an adhesive protein that increases cell-cell and cell-substratum adhesiveness in a variety cellular adhesion assays. Transformation of chick fibroblasts results in decreased quantities of CSP due primarily to a fivefold reduction in CSP biosynthesis, although increased proteolytic degradation and shedding from the cell surface also contribute. The decreased biosynthesis is apparently due to a fivefold reduction in translatable mRNA for CSP. Reconstitution of isolated purified CSP on 14 transformed cell lines from several species results in reversion to a more normal fibroblastic morphology, adhesiveness, cell surface architecture, microfilament bundle organization, motility, and alignment at confluence. Cell surface protein does not restore growth control. The effects of CSP appear to be due to at least two actions, increased cell-substratum adhesion plus altered cell-cell interactions. Untransformed chick cells treated with affinity-purified antibodies to CSP develop the rounded morphology characteristic of many transformed cells that are deficient in CSP (LETS protein). Cell surface protein is found primarily in fibrillar aggregates on the cell surface. These CSP fibrils are relatively immobile and do not affect the mobility of other cell surface components. However, CSP can be eventually redistributed to caplike structures with anti-CSP. Isolated CSP consists of highly asymmetric disulfide-linked dimers and multimers. The interchain disulfide bridges are confined to a short terminal fragment that is readily removed by trypsin. Cell surface protein and cold-insoluble globulin have similar compositions but differ in solubility and amino termini. Cell surface protein contains primarily asparagine-linked oligosaccharides that appear to be responsible for CSP's concanavalin A receptor activity. Inhibition of CSP's glycosylation by treatment with tunicamycin results in decreased CSP due to marked increases in its degradation rate, without inhibition of synthesis or secretion. Studies of this major cell surface glycoprotein have provided insight into the biochemical mechanisms of cellular adhesion, morphology, and social interaction and provide an approach to analyze the dynamics and regulation of protein synthesis, glycosylation, secretion, and turnover.

Glucose metabolism by adult hepatocytes in primary culture and by cell lines from rat liver

The metabolic fate of [U-14C]glucose has been examined in detail in adult rat hepatocytes in primary monolayer culture, as well as in two permanent cell lines--Buffalo rat liver (BRL) and transplantable rat hepatoma (HTC) cells-derived from normal rat liver and from rat hepatoma, respectively. Under defined conditions of incubation, at a glucose concentration of 5.5 mM, the three types of cultured liver cells exhibited pronounced differences in glucose metabolism. Primary cultures, like the intact liver, differed from the cell lines in consuming relatively small amounts of glucose and converting approximately 50% of the total metabolized glucose to lactate. By contrast, the permantent cell lines consumed glucose at a 40-fold greater rate than did primary cultures, converting 80--90% of the carbohydrate to lactate. Oxidative metabolism of glucose carbon also differed among the three types of liver culture. Of the total [U-14C]glucose consumed, primary cultures converted approximately 30% to labeled CO2 per hour, whereas the liver cell lines converted 5--10%. Finally, glucose metabolism in primary culture exhibited adaptation as hepatocytes aged in culture, shifting progressively toward the pattern exhibited by the permanent cell lines. This change occurred over a time course similar to that for other kinds of functional change in hepatocytes in primary culture and thus may be relevant to the general problem of phenotypic alteration in liver cell culture.