Regulation of hepatic acute phase protein synthesis by products of interleukin 2 (IL 2)-stimulated human peripheral blood mononuclear cells

Cancer patients injected with recombinant human IL 2 develop marked changes in serum concentrations of hepatic acute-phase proteins. To determine if this acute-phase response involves a change in the rate of hepatic protein synthesis and if it is due to a direct effect of IL 2 on hepatocytes, human hepatoma-derived hepatocytes (Hep-3B cells) were incubated in medium containing IL 2 or in culture supernatants from IL 2-activated human peripheral blood mononuclear cells (PBMNC). The rate of synthesis of two acute-phase proteins, complement protein factor B and albumin, was determined by the incorporation of a radiolabeled amino acid precursor into newly synthesized protein as measured by analytical gel electrophoresis of immunoprecipitates. IL 2 in concentrations from 1 to 1000 U/ml had no effect on the synthesis of factor B or albumin; conversely, there was a dose-dependent increase in the rate of synthesis of factor B and decrease in albumin synthesis mediated by culture supernatants of IL 2-activated PBMNC. The magnitude of the effect of acute-phase protein synthesis was dependent on the IL 2 concentration used for the activation of PBMNC. The rate of factor B synthesis increased approximately 4.0-fold in the presence of culture supernatants of PBMNC activated with either opsonized heat-killed Staphylococcus albus or with 1000 U/ml IL 2. Preincubation of the IL 2-activated PBMNC culture supernatants with an antiserum specific for recombinant IL 1-beta completely neutralized the capacity of the supernatants to stimulate factor B synthesis, whereas antisera specific for human IL 1-alpha or for tumor necrosis factor had no effect. These results indicate that the indirect effect of IL 2 on hepatic acute phase protein synthesis is mediated by IL 1-beta.     

Copper-induced production of copper-binding supernatant proteins by the marine bacterium Vibrio alginolyticus

Growth of the marine bacterium Vibrio alginolyticus is temporarily inhibited by micromolar levels of copper. During the copper-induced lag phase, supernatant compounds which complex and detoxify copper are produced. In this study two copper-inducible supernatant proteins having molecular masses of ca. 21 and 19 kilodaltons (CuBP1 and CuBP2) were identified; these proteins were, respectively, 25 and 46 times amplified in supernatants of copper-challenged cultures compared with controls. Experiments in which chloramphenicol was added to cultures indicated that there was de novo synthesis of these proteins in response to copper. When supernatants were separated by gel permeation chromatography, CuBP1 and CuBP2 coeluted with a copper-induced peak in copper-binding activity. CuBP1 and CuBP2 from whole supernatants were concentrated and partially purified by using a copper-charged immobilized metal ion affinity chromatography column, confirming the affinity of these proteins for copper. A comparison of cell pellets and supernatants demonstrated that CuBP1 was more concentrated in supernatants than in cells. Our data are consistent with a model for a novel mechanism of copper detoxification in which excretion of copper-binding protein is induced by copper.     

Stimulation of yeast mitochondrial protein synthesis by postpolysomal supernatants from yeast,rat liver,and Escherichia coli

Isolated yeast mitochondria incubated with a protein-synthesizing mixture containing excess oxidizable substrate, amino acids, MgCl₂, an ATP-regenerating system, and optimal levels of [³H]leucine cease protein synthesis after 30 min. Postpolysomal supernatants from either yeast, rat liver, or Escherichia coli can restore protein synthetic activity to depleted yeast mitochondria; however the addition of bovine serum albumin to the incubation mixture did not restore activity. The restored incorporation activity was sensitive to chloramphenicol, insensitive to cycloheximide, and proportional to the protein concentration of the supernatants. Furthermore, addition of all three high-speed supernatants to isolated mitochondria at time zero stimulated the rate of protein synthesis to a greater extent than when these fractions were added to depleted mitochondria. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate revealed that the translation products obtained from mitochondria labeled in vitro in the presence of supernatant fractions were identical to the proteins labeled by mitochondria in vivo; however, the synthesis of the bands corresponding to subunit III of cytochrome oxidase, cytochrome b, and VAR-3 was stimulated to the greatest extent. The stimulatory activity in the supernatants was non-dialyzable, insensitive to treatment with ribonuclease A, but completely abolished by pretreatment with trypsin suggesting that the stimulatory factor(s) is of a protein nature. The postpolysomal supernatants did not incorporate amino acids into protein when incubated without mitochondria. These results suggest that the protein synthetic capacity of mitochondria is apparently limited by extramitochondrial proteins which are present in either yeast, rat liver, or E. coli.     

Copper-induced production of copper-binding supernatant proteins by the marine bacterium Vibrio alginolyticus.

Growth of the marine bacterium Vibrio alginolyticus is temporarily inhibited by micromolar levels of copper. During the copper-induced lag phase, supernatant compounds which complex and detoxify copper are produced. In this study two copper-inducible supernatant proteins having molecular masses of ca. 21 and 19 kilodaltons (CuBP1 and CuBP2) were identified; these proteins were, respectively, 25 and 46 times amplified in supernatants of copper-challenged cultures compared with controls. Experiments in which chloramphenicol was added to cultures indicated that there was de novo synthesis of these proteins in response to copper. When supernatants were separated by gel permeation chromatography, CuBP1 and CuBP2 coeluted with a copper-induced peak in copper-binding activity. CuBP1 and CuBP2 from whole supernatants were concentrated and partially purified by using a copper-charged immobilized metal ion affinity chromatography column, confirming the affinity of these proteins for copper. A comparison of cell pellets and supernatants demonstrated that CuBP1 was more concentrated in supernatants than in cells. Our data are consistent with a model for a novel mechanism of copper detoxification in which excretion of copper-binding protein is induced by copper.     

Reconstitution of active recombinant Shiga toxin (Stx)1 from recombinant Stx1-A and Stx1-B subunits independently produced by E. coli clones

Escherichia coli clones expressing recombinant Shiga toxin (Stx)1-A and recombinant Stx1-B subunits, were established. Culture supernatants of these clones were examined for inhibitory activity on in vitro protein synthesis using luciferase as a reporter enzyme. Culture supernatant of the clone expressing Stx1-A, but not Stx1-B, showed the inhibitory activity. Neither recombinant Stx1-A nor Stx1-B showed Vero cell cytotoxicity. For reconstitution of biologically active toxin, the culture supernatants of the Stx1-A clone and the Stx1-B clone were mixed. The reconstituted recombinant Stx1 showed both Vero cell cytotoxicity and inhibition of in vitro protein synthesis.     

Protein synthesis in postnuclear supernatants from mengovirus-infected Ehrlich ascites tumor cells.

The effect of mengovirus infection on the protein synthetic capacity of Ehrlich ascites tumor cells cultured in vitro was studied in vivo and in vitro employing postnuclear supernatants prepared at various times post-infection in the absence and in the presence of 1% Triton X-100. The amino acid incorporating activities of extracts obtained in the presence of the detergent were reduced by about 30% compared with the capacities of the corresponding postnuclear supernatants prepared in the absence of Triton X-100; but the course of the activity vs. time curve was not influenced by the detergent. Under the conditions employed, the postnuclear supernatants were unable to reinitiate protein synthesis once elongation of nascent polypeptide chains concomitant with ribosome runoff was completed. After mengovirus infection, a gradual disappearance of polysomes from postnuclear supernatants and a simultaneous accumulation of monosomes was observed. The protein-synthesizing activities of normal and infected cells were inversely proportional to the monosome concentrations of their corresponding extracts. Qualitatively, protein synthesis in intact cells and in postnuclear supernatants responded similarly to mengovirus infection. In both cases an initial reduction of host-specific amino acid incorporation was followed by a burst of viral protein synthesis. However, the two activity vs. time curves showed the following significant differences: 1) The activities of extracts from control cells and from mengovirus-infected cells nearly in the infectious cycle were low compared with the activities observed in vivo. 2) In the middle of the infectious cycle, the peak of viral protein synthesis occurred later and the activity was higher in vitro. 3) Finally, in the late period of the infectious cycle the postnuclear supernatants had considerable protein synthesizing activity, at a time when protein synthesis in vivo was nil.     

Stimulation of in vitro mitochondrial protein synthesis by yeast cytoplasmic extracts is caused by guanyl nucleotides

Micromolar concentrations of GDP or GTP stimulate protein synthesis by isolated yeast mitochondria 3- to 10-fold even if alpha-ketoglutarate and an ATP-regenerating system are present. No stimulation is observed with GMP, UTP, CTP, TTP, and the nonhydrolyzable GTP analogues guanyl(beta, gamma-methylene) diphosphate and guanyl imidodiphosphate. This stimulatory effect of exogenously added guanyl nucleotides may answer the long standing question why protein synthesis by isolated mitochondria is so slow. It can also explain previous reports by two other laboratories that a high speed supernatant from yeast cells stimulates protein synthesis by isolated mitochondria. The supernatant contains nondialyzable GMP which is converted to GDP under the conditions used for assaying mitochondrial protein synthesis. The stimulatory effect of high speed supernatants is abolished by 5'-nucleotidase (which degrades GMP) or by trypsin (which destroys supernatant protein(s) necessary for converting GMP to GDP). No evidence was obtained that the stimulatory effect of high speed supernatants was caused by precursors to cytoplasmically made cytochrome c oxidase subunits.     

Secretory protein biosynthesis in snail hemocytes: in vitro modulation by larval schistosome excretory-secretory products

Circulating hemocytes of the snail, Biomphalaria glabrata, synthesize and secrete a variety of polypeptides when maintained in vitro in serum-free medium containing [35S] methionine. SDS-PAGE/fluorographic analysis of supernatants from resistant snail (10-R2-OK strain) hemocyte cultures revealed the presence of numerous labeled polypeptides ranging in Mr from 220 to 14 kDa. Most of these same proteins were also produced by hemocytes of a susceptible B. glabrata strain (M-line), but the overall rate of secretory protein synthesis was reduced from that of resistant snail cells. In addition, excretory-secretory (ES) products contained in supernatants from Schistosoma mansoni miracidial transformation and 1-day primary sporocyst cultures stimulated increases in the synthesis of various polypeptides. Particularly striking was a 3-fold increase in the synthesis of a 66-kDa secretory polypeptide by hemocytes of both snail strains, and a concomitant increase in M-line hemocytes and decrease in 10-R2-OK cells of a 63-kDa polypeptide. Overall, however, the level of ES product-induced secretory protein synthesis was greater in 10-R2-OK snail hemocytes than in those of the M-line strain. Exposure of a nonhemocytic B. glabrata cell line to parasite culture supernatants had no stimulatory/inhibitory effect on labeled protein ouput, suggesting that the observed hemocyte response may be snail cell-type specific. Finally, the larval ES components responsible for modulating hemocyte protein metabolism are mainly concentrated in a heat-stable fraction composed of molecules of greater than 30 kDa. However, the loss of the ability of heated parasite products to stimulate synthesis of certain hemocyte proteins and the presence of minor stimulating activity in a low molecular weight fraction (less than 10 kDa) implies the possible existence of multiple larval components affecting formation of specific hemocyte secretory polypeptides. It is concluded that snail hemocytes are capable of in vitro synthesis and secretion of a variety of methionine-containing polypeptides, and that ES products of early larval schistosomes can modulate (i.e., stimulate or inhibit) this metabolic process. A differential response of susceptible vs. resistant hemocytes to larval products suggests that the degree to which these cells can be metabolically activated may determine their cytotoxic effectiveness.     

Inhibition of protein synthesis by (aminooxy)acetate in rat liver

(Aminooxy)acetate and D-cycloserine, two inhibitors of hepatic transamination reactions, inhibited also protein synthesis in isolated cells and postmitochondrial supernatants from rat liver. Both inhibitors acted in extracts only in concentrations higher than 1 mM. However, while D-cycloserine acted in isolated cells, as in extracts, (aminooxy)acetate inhibits protein synthesis in isolated cells by 50% of the control in the range 0.03-3 mM. NH+4 and H2O2, two by-products of (aminooxy)acetate degradation, inhibited protein synthesis in isolated liver cells, but at such a high concentration that the inhibition of protein synthesis carried out by (aminooxy)acetate cannot be explained by generation of these species. The results point out that the inhibitory action of (aminooxy)acetate on protein synthesis appears to require the integrity of the molecule.     

DNA and immunoglobulin synthesis by rabbit peripheral blood lymphocytes in vitro: complete and incomplete stimulation

Activation of resting (G0) rabbit peripheral blood lymphocytes (PBLs) into DNA synthesis and IgG synthesis was studied using sheep anti-rabbit IgG (SARIgG), protein A, pokeweed mitogen (PWM), and lipopolysaccharide (LPS). DNA synthesis was assayed by [125I]iododeoxyuridine incorporation. IgG synthesis was measured by determination of Ig in culture supernatants by an ELISA assay. Rabbit PBLs cultured with SARIgG or protein A for 48 hr and then without these reagents for 72 hr showed both DNA synthesis and Ig synthesis, whereas PWM and LPS had very little, if any, effect. PBLs stimulated with SARIgG for 6 hr and then without SARIgG for subsequent 114 hr did not become activated into DNA synthesis or IgG synthesis. However, PBLs prestimulated with SARIgG for 6 hr and then with PWM for 114 hr showed prominent DNA and IgG synthesis. LPS also maintained activation of PBLs after prestimulation of these cells with SARIgG, but the effect was much smaller than that of PWM. No evidence was found for production of factors by SARIgG-stimulated PBLs that could, by themselves, either stimulate resting cells or maintain activation of SARIgG-prestimulated cells. These results suggest that anti-IgG and protein A are complete activating mitogens for resting rabbit B cells to proliferate and differentiate into IgG-producing cells, whereas PWM and LPS are not able to activate G0 cells directly, but have a sustaining effect after activation of resting B cells with anti-IgG, either directly or via production of factors by accessory cells.     

Increase of protein synthesis in cell-free system prepared from hypertrophied rat heart during L-triiodothyronine treatment.

During development of rat heart hypertrophy induced by repeated injections of triiodothyronine (T3), cell-free protein synthesis activities of heart post-ribosomal supernatant and of heart polysomes have been measured separately. This was done by complementation respectively with polysomes and post-ribosomal supernatants of adult and newborn rat heart, and of rabbit reticulocytes. In the presence of polysomes of either rat heart or reticulocytes, protein synthesis activity of the supernatant was maximum between the 3rd and the 8th day of treatment. Protein synthesis in the presence of polysomes from triiodothyronine treated rat hearts and of supernatants of both origins was maximum between the 11th and the 15th day.     

Iron- and molybdenum-repressible outer membrane proteins in competent Azotobacter vinelandii.

Azotobacter vinelandii produced three major proteins of 93,000, 85,000, and 81,000 daltons and a minor 77,000-dalton protein in the outer membrane of Fe-limited cells, and these cells were competent for transformation by DNA. The synthesis of these proteins was repressed in Fe-sufficient medium. Mo limitation of nitrogen-fixing cells resulted in the hyperproduction of a 44,000-dalton protein and the production of a minor 77,000-dalton protein in the outer membrane. Mo limitation enhanced competence in Fe-limited medium and induced competence in Fe-sufficient medium. The 44,000-dalton protein was replaced by a 45,000-dalton protein when Fe-sufficient medium also contained NH4+, but the cells were noncompetent. The synthesis of these proteins was repressed in Mo-sufficient medium and by NH4+ in Fe-limited medium. All of the culture supernatants contained a blue-white fluorescent material (absorbance maximum, 214 nm) which appeared to coordinate Fe3+, Fe2+, MoO4(2-), WO3(2-), and VO3(-).     

Phenobarbitone-induced stimulation of protein synthesis in liver of diabetic rat.

The effect of phenobarbitone on liver weight, on the rate of protein synthesis and on the sedimentation profiles of polyribosomes from livers was studied in diabetic rats. The rate of protein synthesis by isolated postmitochondrial supernatants from diabetic rats is lower than that from normal animals. The analysis of polyribosome profiles and the effect of Sephadex chromatography on protein synthesis demonstrated that the reduction was dependent in part on polyribosomal disaggregation and in part on the presence in the cytosol of low molecular weight inhibitor(s). Phenobarbitone administration had the same effect in either diabetic or normal rats in that it increased, (a) the degree of polyribosomal aggregation, (b) the rate of protein synthesis by the isolated postmitochondrial supernatants, (c) liver weight and (d) the activity of the inducible enzyme, NADPH-cytochrome c reductase. Both polyribosomal and soluble factors appear to be involved in the phenobarbitone effect. As the diabetic rats do not secret insulin the results suggest that insulin is not involved in the control of protein synthesis by phenobarbitone. It is suggested that the intracellular redox state has a major influence on the rate of protein synthesis.     

Histamine-releasing activity (HRA). I. Production by mitogen- or antigen-stimulated human mononuclear cells.

Supernatants from 1- to 2-day cultures of human mononuclear cells induced the release of histamine from basophils. Generation of this histamine-releasing activity (HRA) was stimulated by addition of concanavalin A to the cell cultures. Mononuclear cells were also cultured with SKSD and Candida albicans antigens. Stimulation of HRA production by these antigens was correlated with positive delayed skin reactions. Serial dilutions of supernatants assayed for HRA provided a semiquantitative determination of the level of HRA in mitogen- or antigen-stimulated samples. Antigen increased HRA production when added during the first or second day of culture. Generation of HRA probably requires active protein synthesis, since puromycin was inhibitory, and since preformed HRA could not be recovered from lysed cells. HRA was detected in supernatants after 4 hr, and the effects of antigen stimulation were apparent after 8 hr of culture. Replacement of supernatants with fresh culture medium allowed continued synthesis of substantial quantities of HRA during the second day of culture. A linear correlation was observed between the amount of HRA produced and the mononuclear cell concentration. Our findings provide evidence for the interaction of lymphocytes and basophils via a soluble mediator.     

Two novel Streptomyces protein protease inhibitors. Purification, activity, cloning, and expression.

In contrast to the Gram-negative bacteria, Gram-positive bacteria such as Streptomyces lack a mucopolysaccharide cell wall which allows them to produce and secrete a variety of proteins directly into their environment. In an effort to understand and eventually exploit the synthesis and secretion of proteins by Streptomyces, we identified and characterized two naturally occurring abundantly produced proteins in culture supernatants of Streptomyces lividans and Streptomyces longisporus. We purified these 10-kDa proteins and obtained partial amino acid sequence information which was then used to design oligonucleotide probes in order to clone their genes. Analysis of the sequence data indicated that these proteins were related to each other and to several other previously characterized Streptomyces protein protease inhibitors. We demonstrate that both proteins are protein protease inhibitors with specificity for trypsin-like enzymes. The presumptive signal peptidase cleavage sites and subsequent aminopeptidase products of each protein are characterized. Finally, we show that the cloned genes contain all of the information necessary to direct synthesis and secretion of the proteins by Streptomyces spp. or Escherichia coli.     

Macrophage production of fibronectin, a chemoattractant for fibroblasts

Activation of macrophages results in the production of numerous enzymes and effector molecules. One of these monokines released by macrophages can cause directed migration of connective tissue fibroblasts in vitro. Production of this macrophage-derived chemotactic factor for fibroblasts requires activation of the macrophages either in vivo or in vitro and de novo protein synthesis. The chemotactic activity in the macrophage supernatants could be removed by a fibronectin-specific affinity column and was inhibited in the presence of antibodies to fibronectin. Furthermore, chemotactic activity in the depleted macrophage supernatants could be restored by the addition of exogenous fibronectin. Fibronectin was identified in activated macrophage supernatants by an enzyme-linked immunoassay for fibronectin. From these findings it was concluded that activated macrophages release a chemoattractant for fibroblasts and that the primary chemoattractant molecule is fibronectin. The production of fibronectin by activated macrophages may thus serve as an inflammatory mediator that in addition to its other functions can recruit fibroblasts to an area of damaged tissue, where they can proliferate and form the scar tissue necessary for tissue repair. Furthermore, in chronic inflammation, the prolonged activation of macrophages may be related to the extensive fibroblast infiltration and fibrosis that can accompany these lesions.     

Complement-subcomponent-C1-inhibitor synthesis by human monocytes.

By using a radioimmunoassay, C1-inhibitor was found to accumulate in the supernatants of human monocyte cultures. The production of this protein was inhibited reversibly by cycloheximide. When C1-inhibitor synthesis was compared with C2 synthesis, it was found that C1-inhibitor synthesis continued, whereas synthesis of C2 appeared to cease after about 7 days in culture. Immunoprecipitation of supernatants of monocyte cultures that had been pulsed with [35S]methionine showed a specific band with an Mr of 105 000. Immunoprecipitates of the lysates revealed a band of Mr 83 000; this was thought to represent a partially or non-glycosylated precursor of C1-inhibitor. C1-inhibitor produced by the monocytes was shown, by using a haemolytic assay, to be functionally active. However, the functional activity of C1-inhibitor was reduced by only 44% in the presence of cycloheximide, whereas the concentration of this protein in cycloheximide-treated culture supernatants fell by more than 93%. This finding suggests that monocytes secrete a second molecule, which inhibits C1 activity but is distinct from classical C1-inhibitor.     

Shutoff of histone synthesis by Mengovirus infection of Ehrlich ascites tumor cells.

The histone synthesizing capacity of mengovirus-infected Ehrlich ascites tumor cells and of their corresponding postnuclear supernatants was investigated as a funcion of time post-infection. In addition, histone synthesis was compared with the synthesis of other basic host proteins under identical conditions. In the scope of mengovirus infection of Ehrlich ascites tumor cells the less complex fraction comprising basic protein, separated from the acidic proteins by carboxymethyl cellulose chromatography, can be regarded as a representative of total host protein. Histones and the remaining basic host proteins therefore are well suited as easily identifiable indicators of the host protein synthesizing potential of mengovirus-infected Ehrlich ascites tumor cells. The cessation of histone synthesis proceeds faster than the arrest of the synthesis of other basic host protein.     

Cell-free translation systems prepared from starfish oocytes faithfully reflect in vivo activity; mRNA and initiation factors stimulate supernatants from immature oocytes.

Meiotic maturation stimulates a change in the translation of stored mRNAs: mRNAs encoding proteins needed for growth of oocytes are translated before meiotic maturation, whereas those encoding proteins required for cleavage are translated after meiotic maturation. Studies of translational regulation during meiotic maturation have been limited by the lack of translationally active cell-free supernatants. Starfish oocytes are ideal for preparing cell-free translation systems because experimental application of the hormone 1-methyladenine induces their maturation, synchronizing meiosis. We have prepared such systems from both immature and mature oocytes of starfish. Changes in protein synthesis rates and the specificity of proteins synthesized in these cell-free translation supernatants mimic those seen in vivo. Supernatants both from immature and mature oocytes have a high capacity to initiate new translation because 90% of the proteins made are newly initiated from mRNAs. Cell-free supernatants from mature oocytes have a much higher rate of initiation of translation than those from immature oocytes and use the 43S preinitiation complexes more efficiently in initiation of translation. Similarly, we have shown that mRNAs and initiation factors are rate limiting in cell-free translation systems prepared from immature oocytes. In addition, cell-free translation systems prepared from immature oocytes are only slightly, if at all, inhibitory to cell-free translation systems from mature oocytes. Thus, soluble inhibitors, if they exist, are rapidly converted by cell-free supernatants from mature oocytes. The similarities between translation in our starfish cell-free translation systems and in intact oocytes suggests that the cell-free translation systems will be useful tools for further studies of maturation events and translational control during meiosis.