Synthesis of serum proteins by cultures of chick embryo yolk sac endodermal cells

Endodermal cells were isolated from yolk sacs of 3-day chick embryos and cultured for 6 days in Eagle's minimal essential media plus 10% fetal calf serum. During this period cells rapidly lost their ability to synthesize DNA as judged by [3H]thymidine incorporation into DNA. In spite of this loss of DNA synthesis serum protein synthesis and secretion remained at a constant 45% of total protein synthesis and secretion. This was determined by immunoprecipitation of culture media using antibodies directed against embryonic chick serum proteins. Media were also analyzed for the synthesis and secretion of specific serum proteins using polyacrylamide gel electrophoresis. The relative synthesis and secretion of the individual serum proteins followed that previously observed in ovo with the exception of alpha-globulin-a which became undetectable. When culture media were supplemented with ovalbumin or insulin the relative synthesis and secretion of certin specific serum proteins were altered. However, analysis of these same media samples showed that the total amounts of serum protein synthesis and secretion were unaffected.     

Protein synthesis and secretion and RNA and DNA synthesis in human skin fibroblasts in a medium with a low serum content

Human skin fibroblasts, both postnatal and embryonic, were cultured in the stationary phase of growth for 6-10 days in the DMEM with bovine serum (BS), 0.1-0.5% fetal calf serum (FCS) or 1% human serum (HS). On the day 4 of culturing, a considerable increase was observed in the synthesis and secretion of protein by postnatal fibroblasts in the Eagle medium with 0.1-0.5% FCS, or with 0.5% BS, and in medium 199 with 0.1-0.5 BS, or with 0.1 FCS. Maximum synthesis and secretion of 14C-proline labeled protein was observed on day 2 of culturing of cells in the DMEM medium with 1% HS. In the DMEM medium with low serum content, protein synthesis being virtually unchanged, 75-80% of protein was secreted by cells into the culture medium with BS on days 2-4; in the medium with FCS such a high secretion of protein was observed only on day 4. High synthesis of protein by fetal fibroblasts in the DMEM medium with 0.1% BS and high protein secretion in all the media with 0.1% BS or 0.5% FCS were observed. The maximum level of secretion of protein by fibroblasts coincided with a considerable increase in both RNA and DNA syntheses. The data obtained suggest that cells in deep resting state actively react to the composition of the medium as well as to the quality and quantity of the serum. It may also be suggested that the mechanism of protein secretion has an important role in maintenance of the constant level of intracellular proteins in resting cells.     

Granulocyte-macrophage colony-stimulating factor increases synthesis and expression of CR1 and CR3 by human peripheral blood neutrophils

Polymorphonuclear leukocytes (PMN) constitutively synthesize various plasma membrane proteins including CR1(3) (CD35), CR3 (or Mac-1) alpha-chain (CD11b) and MHC class I. PMN are also able to up-regulate rapidly the expression of CR1 and CR3 to the plasma membrane in response to agonists such as FMLP. To determine whether constitutive PMN translation was static or up-regulatable, PMN were cultured in the presence or absence of the cytokine granulocyte-macrophage colony-stimulating factor (GM-CSF) for 8 h. CR1, CR3 and class I proteins immunoprecipitated from lysates of 35S-methionine pulse-labeled PMN were resolved by SDS-PAGE, fluorographed and quantified by densitometry. GM-CSF-treated PMN synthesized 4.5-fold more class I protein, 3.7-fold more CR1, 2.4-fold more CD11b and 3.4-fold more CR3 beta-chain (CD18), compared with untreated control cells. Actinomycin D treatment of replicate samples of PMN decreased the amount of these proteins synthesized by each group of PMN from 30 to 90%, implying that continued translation was required for the increases in protein synthesis. Nascent CR and class I proteins were inserted into the plasma membrane of PMN, thereby supplementing the molecules already expressed on the cell surface. In addition to these longer term effects of GM-CSF, we observed its acute up-regulatory effects on PMN. GM-CSF induced a five- to 12-fold increase in the expression of CR1 and CR3 on the PMN cell surface within 30 min. These increases were both dose- and time-dependent with maximum up-regulation occurring at 25 pM and at 30 min. In contrast to the long term biosynthetic events, this rapid up-regulation was not dependent on protein synthesis but was due instead to mobilization of CR from intracellular compartments similar to those up-regulated by FMLP. These results demonstrate that PMN can respond to microenvironmental stimuli such as GM-CSF both by rapidly up-regulating and increasing translation and expression of functionally important plasma membrane proteins.     

Insulin effects on protein synthesis and secretion in primary cultures of amphibian hepatocytes.

The objective of the present study was to determine the effects of insulin on amphibian hepatocytes in primary culture. Hepatocytes were isolated from adult bullfrogs by collagenase perfusion and maintained as monolayers in serum-free medium. Cells cultured in the continuous presence of insulin exhibited a relatively constant rate of protein secretion over the first four to five days, whereas controls showed an almost three-fold decrease over the same time period. The decline in secreted proteins was equally represented in most exported proteins, except that serum albumin secretion showed twice as much of a decrease relative to the other proteins. The maintenance of protein secretion by insulin was the result of its effect on protein synthesis. The rate of protein synthesis was measured by the incorporation of (3H)-leucine into protein using culture medium containing 0.5 mM leucine, a condition where the specific radioactivity of leucyl-tRNA was shown to be equal to that of (3H)-leucine in the medium. Cultures maintained with insulin for 60 hours synthesized protein at two to three times the rate found in non-insulin treated controls whose rate of protein synthesis was first detectably decreased after nine hours of culture in the insulin-free medium. Sedimentation profiles of polyribosomes from hepatocytes maintained for 60 hours without insulin showed proportionately fewer ribosomes in large polysomes and more in monosomes and free ribosomal subunits than ribosomes from cells cultured with insulin. This result suggests that the decrease in protein synthesis found in the absence of insulin is due to a defect in initiation. Insulin does not exert its effect by regulating cellular levels of ATP; no change in ATP content was found in cells maintained with or without insulin. The results show that insulin maintains high levels of protein synthesis and secretion in amphibian hepatocytes. The hepatocytes in monlayer culture provide a system to study the molecular mechanisms involved in the translational control of protein synthesis by insulin.     

Effect of tunicamycin on the secretion of serum proteins by primary cultures of rat and chick hepatocytes. Studies on transferrin, very low density lipoprotein, and serum albumin.

Using rat or chick hepatocyte monolayers, we have studied the effect of tunicamycin, a specific inhibitor of protein glycosylation, on the synthesis and secretion of serum proteins. Tunicamycin inhibited glucosamine incorporation into rat liver transferrin and the apoprotein B chain of chick liver very low density lipoprotein (VLDL) by 75 to 90%. In contrasts, amino acid incorporation into these two glycoproteins, as well as into the normally unglycosylated proteins, rat serum albumin and apoprotein A of chick liver VLDL, was decreased by only 10 to 25% in the presence of the antibiotic. Despite the inhibitory effect of tunicamycin on glycosylation, secretion of all four proteins was virtually unimpaired. Thus, the carbohydrate moieties of rat liver transferrin or apoprotein B of chick liver VLDL do not appear to play an essential role in the secretion process.     

Interleukin-6 is the major regulator of acute phase protein synthesis in adult human hepatocytes

The three monokines interleukin-1 beta (IL-1 beta), tumor necrosis factor alpha (TNF alpha), and interleukin-6 (IL-6) modulate acute phase plasma protein synthesis in adult human hepatocytes. Only IL-6 stimulates the synthesis of the full spectrum of acute phase proteins as seen in inflammatory states in humans, i.e. synthesis and secretion of C-reactive protein, serum amyloid A, fibrinogen, alpha 1-antitrypsin, alpha 1-antichymotrypsin and haptoglobin are increased while albumin, transferrin and fibronectin are decreased. IL-1 beta as well as TNF alpha, although having a moderate effect on the positive acute phase proteins and inhibiting the synthesis of fibrinogen, albumin and transferrin, fail to induce serum amyloid A and C-reactive protein. These data suggest that IL-6 plays the key role in the regulation of acute phase protein synthesis in human hepatocytes.     

Correlation of the rhythms of protein synthesis and secretion in a hepatocyte monolayer culture

In primary monolayer culture of hepatocytes, circahoralian rhythms of protein synthesis and secretion were discovered. In one of the hepatocyte populations the rhythmic cycle of protein secretion was found to be about twice as long as that of protein synthesis. Combination of different experimental variants such as the impulse and the long-term labelling of proteins or inhibition of protein synthesis, revealed that the secretion rhythms were predetermined by the secretion of both newly formed proteins and those stored in the cell for a long time. Upon the inhibition of protein synthesis with cyclohexeimide, the protein secretion in the monolayer changes its rhythmic pattern for a constant rate secretion. Possible causes of the alteration of circahoralian variations of protein synthesis are discussed.     

Oestrogen induction of riboflavin-binding protein in immature chicks. Nature of the secretory protein.

The riboflavin-binding protein isolated from sera of oestrogen-treated male chicks as well as that synthesized and secreted in vitro by the chicken liver have the same molecular size as that of the egg-yolk protein. Functionally the serum and yolk proteins are similar. This is in contrast with the hormone-induced synthesis, secretion and deposition of phosvitin and lipovitellin in the ovary.     

Alterations in albumin secretion and total protein synthesis in livers of thyroidectomized rats.

Perfused rat livers and isolated rat hepatocytes exhibited a 50% decrease in the secretion of both albumin and total secretory proteins after thyroidectomy. In contrast, synthesis of non-secretory proteins was decreased by only 20% from the rates observed in liver preparations from euthyroid rats. These observations suggested a disproportionate effect of thyroidectomy on the synthesis of secretory proteins compared with non-secretory proteins. Disproportionate decreases in the synthesis of albumin in other endocrine-deficient states such as hypophysectomy and diabetes had previously been shown to be associated with decreases of similar magnitude in the relative abundance of albumin-mRNA sequences. In contrast, thyroidectomy did not affect the activity or amount of albumin mRNA in total liver poly(A)-containing RNA when assayed by cell-free translation and by hybridization with complementary DNA, respectively. Furthermore, labelling experiments in vivo demonstrated that albumin synthesis represented 12.9 +/- 0.5% and 12.4 +/- 0.4% of total protein synthesis in livers of thyroidectomized and euthyroid rats respectively. Therefore the fall in secretion of albumin and total secretory protein after thyroidectomy did not appear to be a reflection of disproportionate decreases in the synthesis of these proteins. Instead, defects in steps involved in the post-synthetic processing and secretion of albumin are suggested. A number of comparisons, including ribosome half-transit times, the size distributions of total and albumin-synthesizing polyribosomes, and the fraction of RNA present as inactive ribosomes, provided evidence that the overall decrease in protein synthesis after thyroidectomy was not due to generalized alterations in translational processes. Instead, the decrease in total protein synthesis appeared to reflect the RNA content of the liver, which fell in proportion to th decrease in protein synthesis.     

Quantitative Analysis of Protein Synthesis Altered by Estrogen in Cultured Xenopus Liver Parenchymal Cell

Using the primary culture system of male Xenopus laevis hepatocytes consisting of more than 95% parenchymal cells, the effect of estradiol-17 β (10⁻⁶M) on protein synthesis was quantitatively analyzed by ³H-leucine incorporation kinetics and the estimation of specific radioactivity of newly synthesized secretory protein. The cells in a well defined culture revealed high plating efficiency and very low DNA synthetic activity. The cultured cells could synthesize several secretory proteins containing serum albumin. The pattern of secreted proteins in SDS-polyacrylamide gel electrophoresis (SDS-PAGE) did not alter with culture time but secretion rate of protein increased for 7 days, starting on the third day following inoculation. Estradiol added to the culture media extensively induced the synthesis of yolk precursor protein vitellogenin which accounted for 40–50% of the overall secretory protein synthesis and 20–30% of the total protein synthesis on day 7 of estradiol treatment. Ultimately, the total protein synthesis and secretory protein synthesis were stimulated 1.2–1.3 fold and 2.0–2.2 fold, respectively, over those of the control cells cultured in the absence of estradiol. These results indicated that the stimulation of protein synthesis was largely due to vitellogenin production. Such an estradiol-dependent stimulation of protein synthesis was also detected in the low molecular weight protein(s). On the other hand, albumin synthesis was evidently reduced by estradiol. Thus, estradiol had two different effects on protein synthesis.
The results obtained in this study will be discussed in relation to the findings o in vivo experiments.     

Pattern of ovarian protein synthesis and secretion during the reproductive cycle of Scotophilus heathi: synthesis of an albumin-like protein

Ovarian proteins synthesized de novo and secreted in vitro were investigated during different stages of the reproductive cycle of Scotophilus heathi. We found increased ovarian protein synthesis and secretion during the recrudescence and the preovulatory periods, coinciding with two peaks of follicular development and steroidogenesis. The ovaries synthesized protein at a low rate during quiescence and the late phase of delayed ovulation. In vitro analysis using ³⁵S-methionine incorporation showed increased synthesis of 66 kDa protein during delayed ovulation, but secretion of this protein declined markedly during the preovulatory period. N-terminal sequencing of the 66 kDa protein showed that it shares 70% homology with human serum albumin. Immunocytochemistry indicated that this protein is found primarily in the granulosa cells of the follicles. Whether the increase in albumin production by the ovaries during delayed ovulation is associated with a hyperinsulinemic and hyperandrogenic condition requires further investigation.     

Effects of dexamethasone and 5-bromodeoxyuridine on protein synthesis and secretion during in vitro pancreatic development

Protein synthesis and secretion during in vitro pancreatic development and after treatment with the glucocorticoid dexamethasone and the thymidine analog 5-bromodeoxyuridine (BrdU) was monitored using two-dimensional gel electrophoresis. At 14 days gestation, the synthesis of more than 200 proteins and the secretion of a complex set of proteins was detected. The relative rate of synthesis and secretion of the majority of this set of proteins decreased dramatically during development; after 6 days of culture most were no longer detected. In contrast, the synthesis and secretion of pancreas-specific exocrine proteins amylase, a Sepharose binding protein (protein 2), and chymotrypsinogen first detected after one day in culture, increased throughout the 6-day culture period. Other pancreatic digestive (pro)enzymes normally found in the adult such as the basic form of chymotrypsinogen, lipase, ribonuclease, and trypsinogen were not detected during the culture period. Thus at least two distinct regulatory events are involved in the expression of the exocrine genes during development. Dexamethasone treatment during the 6-day culture period selectively increased the synthesis of amylase and several other minor secretory proteins. BrdU treatment caused major changes in the protein synthetic and secretory patterns of the pancreas as well as in morphogenesis. BrdU treated pancreases showed greatly reduced synthesis of amylase, protein 2, and chymotrypsinogen and prolonged synthesis of many proteins normally detected only at early stages of pancreatic development. BrdU treatment also stimulated the secretion of a set of proteins ostensibly associated with duct cells. Thus, BrdU specifically alters the developmental program of the pancreas.     

Reduced expression of SIRT1 is associated with diminished glucose-induced insulin secretion in islets from calorie-restricted rats

Alterations in food intake such as caloric restriction modulate the expression of SIRT1 and SIRT4 proteins that are involved in pancreatic β-cell function. Here, we search for a possible relationship between insulin secretion and the expression of SIRT1, SIRT4, PKC and PKA in islets from adult rats submitted to CR for 21 days. Rats were fed with an isocaloric diet (CTL) or received 60% (CR) of the food ingested by CTL. The dose-response curve of insulin secretion to glucose was shifted to the right in the CR compared with CTL islets (EC₅₀ of 15.1±0.17 and 10.5±0.11 mmol/L glucose). Insulin release by the depolarizing agents arginine and KCl was reduced in CR compared with CTL islets. Total islet insulin content and glucose oxidation were also reduced in CR islets. Leucine-stimulated secretion was similar in both groups, slightly reduced in CR islets stimulated by leucine plus glutamine but higher in CR islets stimulated by ketoisocaproate (KIC). Insulin secretion was also higher in CR islets stimulated by carbachol, compared with CTL islets. No differences in the rise of cytosolic Ca²⁺ concentrations stimulated by either glucose or KCl were observed between groups of islets. Finally, SIRT1, but not SIRT4, protein expression was lower in CR compared with CTL islets, whereas no differences in the expression of PKC and PKA proteins were observed. In conclusion, the lower insulin secretion in islets from CR rats was, at least in part, due to an imbalance between the expression of SIRT1 and SIRT4.     

Pattern of ovarian protein synthesis and secretion during the reproductive cycle of Scotophilus heathi: synthesis of an albumin-like protein.

Ovarian proteins synthesized de novo and secreted in vitro were investigated during different stages of the reproductive cycle of Scotophilus heathi. We found increased ovarian protein synthesis and secretion during the recrudescence and the preovulatory periods, coinciding with two peaks of follicular development and steroidogenesis. The ovaries synthesized protein at a low rate during quiescence and the late phase of delayed ovulation. In vitro analysis using 35 S-methionine incorporation showed increased synthesis of 66 kDa protein during delayed ovulation, but secretion of this protein declined markedly during the preovulatory period. N-terminal sequencing of the 66 kDa protein showed that it shares 70% homology with human serum albumin. Immunocytochemistry indicated that this protein is found primarily in the granulosa cells of the follicles. Whether the increase in albumin production by the ovaries during delayed ovulation is associated with a hyperinsulinemic and hyperandrogenic condition requires further investigation.     

Extracellular Enzyme Secretion by Pseudomonas lemoignei

The ability of succinate to repress the secretion of Pseudomonas lemoignei poly-beta-hydroxybutyrate depolymerase was a function of pH. Repression only occurred when the pH of the medium was 7.0 or less. At a higher pH, lack of sensitivity to succinate concentration may have been due to a limited ability to transport succinate. Actively secreting cultures (at pH 7.4) continued to secrete enzyme for approximately 30 min after the pH was rapidly decreased to pH 6.8, even though sufficient succinate was present to repress enzyme synthesis. Similarly, after the addition of rifampin to secreting cultures, there was a 30-min delay before secretion was inhibited. Evidence is presented which suggests that continued secretion may be the result of depolymerase messenger ribonucleic acid accumulation within the cells. Studies with chloramphenicol indicated that de novo protein synthesis is necessary for the secretion of poly-beta-hydroxybutyrate depolymerase and that exoenzyme is not released from a preformed pool. Studies with various inhibitors of protein synthesis indicated that synthesis of exoenzyme is 5 to 10 times more susceptible to inhibition than is the synthesis of cell-associated proteins.     

Synthesis of serum proteins by cultured aggregates from endodermal cells of the area opaca of the primitive streak chick embryo

Summary The pattern of serum protein synthesis and secretion in aggregates of extraembryonic endoderm cells (EEC) from the area opaca of primitive streak chick embryos was studied. EEC aggregates were cultured for various time intervals and serum proteins were detected using sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and fluorography. Serum proteins were identified based on their comigration with reference proteins from 4 day chick embryo serum and with reference proteins from egg white albumen and chicken serum. A number of serum proteins were detected in EEC aggregates including: two variants of immunoglobulin (IgG), four variants of transferrin, a protein with a molecular weight of 66 500 which may correspond to globulins, prealbumin, and a protein with a molecular weight of 38 600 (serum protein 11) which remains unidentified. These proteins were also detected in the culture medium. The banding profiles of EEC extracts and culture medium were compared over various time intervals of culture (6, 18 and 30 h). The IgGs, transforms and serum protein 11 decreased in concentration in EEC extracts over the culture interval. These proteins as well as prealbumin, were detected in the culture medium. A number of proteins were synthesized by EEC, as determined by radiolabelled amino acid incorporation. All of the labelled serum proteins were detected in the culture medium, not in EEC extracts. These results suggest that serum proteins are synthesized by EEC then rapidly released into the medium. Labelled serum proteins detected in the culture medium include prealbumin and an unidentified serum protein (serum protein 14) which migrates with the tracking dye, both synthesized early in culture (6 h), and transferrin which was synthesized later (18 h) during culture.     

Regulation of protein synthesis and degradation in L8 myotubes. Effects of serum, insulin and insulin-like growth factors.

We have examined the regulation of protein turnover in rat skeletal myotubes from the L8 cell line. We measured protein synthesis by the rates of incorporation of radiolabelled tyrosine into protein in the presence of a flooding dose of non-radioactive tyrosine. We monitored degradation of proteins labelled with radioactive tyrosine by the release of acid-soluble radioactivity into medium containing excess nonradioactive tyrosine. Extracellular tyrosine pools and intracellular tyrosyl-tRNA equilibrate rapidly during measurements of protein synthesis, and very little reutilization of the radiolabelled tyrosine occurs during degradation measurements. Measured rates of protein synthesis and degradation are constant for several hours, and changes in myotube protein content can be accurately predicted by the measured rates of protein synthesis and degradation. Most of the myotube proteins labelled with radioactive tyrosine for 2 days are degraded, with half-lives (t1/2) of approx. 50 h. A small proportion (less than 2.5%) of the radiolabelled proteins are degraded more rapidly (t1/2 less than 10 h), and, at most, a small proportion (less than 15%) are degraded more slowly (t1/2 greater than 50 h). A variety of agents commonly added to primary muscle cell cultures or to myoblast cell lines (18% Medium 199, 1% chick-embryo extract, antibiotics and antifungal agents) had no effect on rates of protein synthesis or degradation. Horse serum, fetal bovine serum and insulin stimulate protein synthesis and inhibit the degradation of long-lived proteins without affecting the degradation of short-lived proteins. Insulin-like growth factors (IGF)-1 and -2 also stimulate protein synthesis and inhibit protein degradation. The stimulation of protein synthesis and the inhibition of protein degradation are of similar magnitude (a maximum of approx. 2-fold) and display similar sensitivities to a particular anabolic agent. Insulin stimulates protein synthesis and inhibits protein degradation only at supraphysiological doses, whereas IGF-1 and -2 are effective at physiological concentrations. These and other findings suggest that IGFs may be important regulators of skeletal muscle growth during the fetal and early neonatal periods.     

Elevated synthesis of human alpha 1-antitrypsin hinders the secretion of murine alpha 1-antitrypsin from hepatocytes of transgenic mice

alpha 1-Antitrypsin (AAT) is a major hepatic secretory protein. The elevated synthesis of human AAT within hepatocytes of transgenic mice results in its accumulation within a subset of distended cisternae of the rough endoplasmic reticulum. The protein does not accumulate in large insoluble aggregates as is the case for the human PiZ AAT variant. Furthermore, the accumulated protein is not associated with immunoglobulin heavy chain binding protein. Transgenic animals exhibiting an elevated synthesis and subsequent intrahepatic accumulation of human AAT exhibit reduced serum levels of murine AAT as a result of its hindered secretion and accumulation within the rough endoplasmic reticulum. Interestingly, the secretion of murine transferrin and albumin which represent glycosylated and non-glycosylated hepatic secretory proteins, respectively, is unaffected. Overall, these results demonstrate that the elevated synthesis of human AAT can hinder the export of murine AAT from the hepatic rough endoplasmic reticulum in an apparently specific manner.     

Insulin-like growth factor binding protein (IGFBP-3), an inhibitor of serum growth factors other than IGF-I and -II.

Our results show that an insulin-like growth factor binding protein, IGFBP-3, purified from rat serum, is an inhibitor of chick embryo fibroblast (CEF) growth. It abolished DNA synthesis in CEF stimulated by IGF-I as well as by human serum. Rat IGFBP-3 and IDF45 (an inhibitory diffusible factor secreted by mouse cells) had the same activities, confirming that they have an intrinsic capacity to inhibit serum stimulation and may be considered as growth inhibitors. Our data show that inhibition by IGFBP-3 of serum stimulation was not simply the result of its inhibition of IGF present in the serum: 1) While anti-IGF-I IgG was able to completely inhibit stimulation induced by added IGF-I, it did not decrease stimulation induced by 1% human serum. Anti-IGF-II IgG inhibited the stimulation induced by added IGF-II, but only 25% decreased the stimulation induced by 0.7% serum. The percent inhibition was not significantly increased when the concentration of serum was decreased to 0.2%, which induced 140% stimulation of DNA synthesis; 2) stimulation by 0.2% serum was much more inhibited by IGFBP-3 than by IgG anti IGF-II; 3) after separation of IGF-I and IGF-II from serum by chromatography of acidified serum proteins on BioGel P150, the remaining serum proteins (with a molecular mass greater than 45 kDa) which were depleted in IGF-I and -II (verified by RIA determination) still stimulated DNA synthesis, and this stimulation was 80% inhibited by IGFBP-3.