The synthesis of phosvitin in vitro by slices of liver from the laying hen

1. Slices of liver from laying hens incorporated Na₂¹⁴CO₃ and NaH₂³²PO₄ into phosvitin. Slices of liver from immature birds did not do so to any appreciable extent. The ³²P was incorporated into O-phosphorylserine in the phosvitin molecule. 2. Kidney, spleen, muscle, large and small intestine, ovary and oviduct from laying birds did not incorporate Na₂¹⁴CO₃ into phosvitin. 3. Slices of liver from laying hens carried out a net synthesis of phosphoprotein under the standard conditions of incubation. Slices from the livers of immature pullets did not do so. 4. Liver from the laying hen incorporated [2-¹⁴C]glycine, [3-¹⁴C]serine and [2-¹⁴C]glutamic acid into phosvitin. Part of the glycine was shown to be present as serine in the final product. 5. Slices of liver from immature birds treated with oestradiol synthesized phosvitin from [2-¹⁴C]glycine, but the addition of oestrogens in vitro to slices from untreated immature birds did not promote synthesis during a 3 hr. incubation period.     

Biochemical and Cytological Analyses of RNA Synthesis in Kinetin-treated Pea Root Parenchyma

Excised cortical parenchyma from the pea root (cv. Little Marvel) responds to kinetin/auxin treatment with an increased rate of RNA synthesis well before reinitiating DNA synthesis. Few cells synthesize RNA in the 1st hour of culture. In the presence of kinetin/auxin, the nuclear labeling index increases 2.5-fold as compared to control cultures. The RNA synthesis response has an apparent lag period of 2-4 hours as shown by double label ([³H]adenosine/[¹⁴C]adenosine) experiments. Qualitatively, the RNA synthesized at 4-6 hours sediments between 18S and 5S. The RNA synthesized at 14-16 hours and 24-26 hours is primarily ribosomal RNA when kinetin is present. In the absence of kinetin, no clear pattern of RNA synthesis emerges.     

Oostatic hormone inhibits biosynthesis of midgut proteolytic enzymes and egg development in mosquitoes

Injection of partially purified oostatic hormone (0.7 μg) into female Aedes aegypti inhibited egg development, proteolytic enzyme activity, and blood digestion in the midgut, whereas control injections of saline or insulin chain A (0.7 μg) did not affect these processes. Oostatic hormone given by enema, on the other hand, did not inhibit proteolytic enzyme activity, indicating that the hormone acts outside the midgut. A single injection of oostatic hormone (0.7 μg) caused a 1.7–1.5-fold reduction in activity of trypsinlike enzymes during blood digestion, with a 10-h delay in peak activity. Using [1,3-³H]diisopropylfluorophosphate (DFP) in the presence of 8 mM tosylamide-2-phenylethyl chloromethyl ketone, the synthesis of trypsinlike derivatives was followed in the midgut of female A. aegypti. A 4-fold reduction in [1,3-³H]diisopropylphosphoryl-trypsinlike derivatives was noted after oostatic hormone treatment. Several isozymes that are normally synthesized were absent in the presence of DFP, as assessed by polyacrylamide gel electrophoresis. Injection of oostatic hormone into decapitated and ovariectomized females that did not synthesize ecdysteroids inhibited trypsinlike enzyme synthesis and blood digestion in the midgut, indicating that oostatic hormone inhibits the midgut cells and not the ovary or the brain's endocrine system. Comparison between oostatic hormone and soybean trypsin inhibitor indicated that the former inhibited trypsin synthesis whereas the latter inhibited trypsin activity. A. aegypti oostatic hormone is not species specific and injections of the hormone into Culex quinquefasciatus, Culex nigripalpus, and Anopheles albimanus caused inhibition of egg development, blood digestion, and synthesis of trypsinlike enzymes. A direct relation between oostatic hormone synthesis and the regulation of trypsinlike activity in the midgut is proposed.     

The Metabolism of Serum Proteins in Neonatal Rabbits

1. Incorporation of S³⁵-labeled amino acids into serum proteins has been studied in neonatal and developing rabbits. It was found that, per unit weight, neonatal rabbits synthesized only about 1/36 of the gamma globulin, 1/7 of the beta globulin, ½ of the alpha globulin, and ⅛ of the albumin that an adult synthesized. The growing rabbit developed the ability to synthesize various serum proteins at different times. 2. Plasma volumes and serum protein concentrations were determined at different times during the growth period of the rabbit. Plasma volumes were found to be 1 and ½ times larger in newborn animals than in adults, with a gradual decline to the adult level. The total serum protein concentration at birth was about 60 to 65 per cent of the adult value and gradually increased with growth as the plasma volume decreased. 3. Half-lives of homologous albumin and gamma globulin were studied. The half-life of albumin in neonates was nearly twice as long as the half-life in adults, the latter value being reached at 1 month of age. The half-life of gamma globulin in neonates was more than twice as long as the half-life in adults and reached adult values at 2 to 3 months. 4. Attempts were made to alter serum protein metabolism. Gamma globulin synthesis early in life was augmented with antigen injections.     

Density labeling of proteins with 13C-labeled amino acids: no accumulation of an inactive alpha-amylase precursor in barley aleurone cells.

Gibberellic acid enhances α-amylase (EC 3.2.1.1) production in isolated barley aleurone layers after a lag period of 4 to 8 h, and most of the enzyme is produced after 12 h of hormone treatment. Amino acids necessary for protein synthesis in barley aleurone layers are derived from the degradation of storage proteins in this tissue. Since bromate is an inhibitor of barley protease, in the presence of bromate the production of α-amylase in aleurone layers becomes dependent on exogenous amino acids. We have incubated aleurone layers with bromate plus ¹³C-labeled amino acids and [³H]leucine from 0 to 24, 0 to 12, and 12 to 24 h after the application of gibberellic acid. The chemical quantity of [³H]leucine was negligible in comparison to that of ¹³C-labeled amino acids. Therefore, any density shift of proteins observed must be due to the incorporation of ¹³C-labeled amino acids. The density shift of α-amylase and that of newly synthesized proteins (radioactivity profile) were determined by isopycnic centrifugation in CsCl density gradients. The density shift of α-amylase isolated from aleurone layers incubated with ¹³C-labeled amino acids from 12 to 24 h after the addition of hormone was much larger than that of α-amylase isolated from aleurone layers incubated with ¹³C-labeled amino acids from 0 to 12 h of hormone treatment. By comparing the density shift of α-amylase with that of newly synthesized proteins, it is apparent that essentially all the amylase molecules are de novo synthesized. We can conclude that there is little or no accumulation of an inactive α-amylase precursor in barley aleurone cells between the time of the application of gibberellic acid and the time of the rapid increase in α-amylase activity.     

The site of synthesis of mitochondrial proteins in Krebs II ascites-tumour cells

At 22° in Earle's medium, Krebs cells synthesize proteins. After a brief `pulse' with [<sup>14</sup>C]valine followed by a `chase' of [¹²C]valine the radioactivity appears first in microsomes and is transferred after `chase' to the cell sap. Kinetics of labelling of the mitochondrial protein are different from that of either microsomal or cell-sap protein. When Krebs cells in buffer are mixed with ribonuclease in water the nuclease penetrates the cell membrane. The ribonuclease-treated cells are still viable but have lost most of their cytoplasmic ribosomes (electron micrograph). Such cells still synthesize mitochondrial protein at near normal rate but synthesis of microsomal protein is severely inhibited. The results indicate that some mitochondrial proteins are synthesized independently of the microsome–cell-sap system.     

Effects of colchicine and 2-Br-alpha-ergocryptine-methane-sulfonate (CB 154) on the release of prolactin and growth hormone by functional pituitary tumor cells in culture

The effects of colchicine and 2-Br-α-ergocryptine-methane-sulfonate (CB 154) on the release of prolactin and growth hormone have been studied in a clonal strain of rat pituitary tumor cells (GH₃) in monolayer culture. These cultures produce both prolactin and growth hormone and release both proteins spontaneously into the medium without storing them in large amounts. Immunological methods were used to measure both intracellular and extracellular concentrations of the hormones. Colchicine (5 × 10^?6 M for 3 hours) caused a 2- to 3-fold increase in intracellular concentrations of prolactin and growth hormone but, under basal conditions, had little or no measurable effect on the amounts of hormone accumulated in the medium during the course of the standard three hour treatment period. This latter finding evidently is due to a lag in the onset of drug action. Colchicine had little or no effect on accumulation of extracellular prolactin during the first two hours of treatment whereas such accumulation was depressed by over 60% during the third hour of treatment. Previous studies have shown that treatment of GH₃ cells with thyrotropin releasing hormone (TRH) and hydrocortisone (HC) increases both intra and extracellular levels of prolactin and growth hormone, respectively. In cultures treated with TRH (5 × 10^?8 M), colchicine (5 × 10^?6 M for 3 hours) increased intracellular prolactin by about 70% and decreased extracellular hormone by 10%. In cultures treated with HC (3 × 1O^?6 M), colchicine increased intracellular growth hormone by more than 100% and decreased medium concentrations of the hormone by 15%. Colchicine did not significantly alter total hormone (intracellular + extracellular) accumulation, cellular uptake of ³H-amino acids, or total cell protein synthesis. The synthetic ergot alkaloid, CB 154, (3.3 × 10^?6 M for 3 hours) caused an 80% increase in intracellular, and a nearly 50% decrease in extracellular, prolactin without affecting the accumulation of growth hormone, the uptake of ³H-labeled amino acids, or overall protein synthesis in the cultures. Elevation of medium potassium concentration from a basal value of 5.3 mM to 3–5 × 10^?2 M (by addition of KCl) decreased intracellular levels of prolactin by 85% and growth hormone by 55%. These effects of high potassium were blocked by colchicine and by CB 154. We conclude that colchicine, after a lag period of two hours, acts to inhibit the release of prolactin and growth hormone from GH₃ cells. By the end of three hours of treatment, this inhibition is over 60% complete in the case of prolactin. The qualitatively different effects of colchicine and CB 154 on prolactin and growth hormone release suggest that these two secretory blocking agents probably act on GH₃ cells by different mechanisms.     

Retinoic acid-induced differentiation of F9 embryonal carcinoma cells

The ability of retinoic acid (RA) to induce differentiation in embryonal carcinoma (EC) cells was examined by growing mouse F9 cells in a medium containing 1 μM RA. The altered properties of the cells became apparent after a lag period of approx. 24 h and were fully expressed after 5 days. The RA-induced phenotype was characterized by changes in cell morphology, slowing of the rate of cell multiplication, reduced DNA and protein synthesis, altered pattern of polypeptide synthesis and changes in cell surface components. The slowing of cell multiplication and general reduction in the rate of protein synthesis was paralleled by changes in the relative rates at which different polypeptides were synthesized. Two-dimensional gel electrophoretic analysis of [³⁵S]methioninelabelled cell proteins showed an altered relative synthesis of at least fifty polypeptides. The relative rate of synthesis of two components of the cytoskeleton identified as vimentin and tropomyosin were shown to increase.     

Regulation of RNA synthesis in plant cell culture: delayed synthesis of ribosomal RNA during transition from the stationary phase to active growth

Ribosomal RNA synthesis was studied during the early phases of growth activation in a cell suspension culture derived from peanut (Arachis hypogaea, L.) cotyledon. Upon dilution from stationary phase, these cells show a characteristic lag of 3 days before the commencement of cell division. An analysis of the nature of RNA synthesized during this early period of growth showed that the cells obtained immediately upon dilution from stationary phase synthesize primarily messenger RNA and essentially no ribosomal RNA. The synthesis of ribosomal RNA is delayed for about 24 hr after which it rises sharply resulting in a 2- to 3-fold accumulation of ribosomal RNA per cell during the subsequent 24-hr period. Both the messenger RNA and the ribosomal RNA were characterized by their cellular localization; by sucrose and CsCl gradient analyses, and by the determination of their base ratios.It would appear that a major facet of the lag phase in the cell growth is the diversion of a significant part of the RNA biosynthetic apparatus from the synthesis of messenger RNA to that of ribosomal RNA.     

Properties of chitin synthase in homogenates from Chironomus cells

Homogenates of Chironomus cells synthesize chitin as effectively as intact cells. Chitin is produced in a dose-dependent manner, when GlcN, GlcNAc, or UDP-GlcNAc is used as precursor. Due to the lability of UDP-GlcNAc incorporation of this substrate is underestimated. No allosteric effect is observed when GlcN or GlcNAc is used as a substrate. Chitin synthesis is stimulated by Mg²⁺ and inhibited by uridine monophosphate (UMP), uridine diphosphate (UDP), and uridine triphosphate (UTP). The apparent temperature optimum is 30°C, the apparent pH optimum is 5.5–6. Addition of the chitinase inhibitor allosamidin does not enhance chitin synthesis significantly. The time course of chitin formation reveals a lag period of about 12 h, which can be overcome by trypsin treatment. Addition of protease inhibitors prevents chitin synthesis.     

The role of RNA and protein synthesis in mediating the action of MSH on mouse melanoma cells.

Exposure of mouse melanoma cells in culture to MSH (melanocyte stimulating hormone) results in a marked increase in tyrosinase (O-diphenyl: O₂ oxidoreductase) activity following a lag period of 6–9 hours. Within 20 minutes after exposure of cells to MSH, the intracellular levels of cyclic AMP rise to levels which are ten times those of controls but fall to concentrations twice control values by 60 minutes. Transient increases in both protein and RNA synthetic rates also occur following MSH administration correlating in time with the dramatic but rapidly decaying increase in cellular cyclic AMP. The increase in tyrosinase activity observed in response to either MSH, dibutyryl cAMP, or theophylline, is completely suppressed by the addition of either cycloheximide (0.28 μg/ml) or actinomycin D (0.05 μg/ml) as is the basal activity of the enzyme. Results from ¹⁴C/³H leucine studies suggest that MSH may cause increased $\text{de}$$\text{novo}$ synthesis of tyrosinase.     

Maturation and germination of Phaseolus vulgaris embryonic axes in culture

In this study of embryo development in Phaseolus vulgaris L., we found that immature embryonic axes placed in culture show a growth lag before germinating. The length of this lag phase varies according to axis age at excision, but is not affected by transfer to fresh medium, alteration of sucrose concentration between 0.5 and 2%, or whether the culture medium is liquid or agar-solidified. The lag phase was shortened by both actinomycin D and cordycepin treatment, and by treatment with 10^-5 to 10^-6 M benzyladenine. The effect of abscisic acid (ABA) varied with concentration: below a certain level, it had no effect on the lag phase, but above that level it inhibited, germination. This threshold concentration was 10^-7 M for 20-d-old axes but increased to 10^-5 M by the time the axes were 32 to 34 d old. To determine whether the axes were continuing their embryonic development during the lag phase, we tested them for desiccation-tolerance and for synthesis of phaseolin, a seed storage protein which is specific for embryos of P. vulgaris. The ability to germinate after rapid desiccation was acquired by axes at 26 d past anthesis; when axes younger than this were placed in culture, they developed desiccation-tolerance during the lag phase of growth, indicating that they were continuing embryonic maturation. Phaseolin was present in isolated axes, although at lower levels than in cotyledons. It accumulated during axis development in parallel with total protein, staying at about 1% of total protein content. When isolated immature axes were pulsed with ³H-or ¹⁴C-amino acids, they incorporated label into phaseolin, shown by precipitation with anti-phaseolin antibody. Isolated axes from mature seeds, however, did not synthesize detectable amounts of phaseolin. Immature axes cultured in vitro for a period of one to several days continued synthesizing phaseolin until the day prior to visible germination. Treatment of cultured axes with ABA increased the amount of precursor amino acids incorporated into protein, but had a small or no effect on the relative proportion of phaseolin synthesized. We conclude that P. vulgaris axes in culture continue to develop embryonically for a period of time which seems to be under intrinisc control by the axis. This contrasts with precocious germanation, a pattern of embryo behavior seen in many other species. When such embryos are excised from seeds while immature and placed in culture, they switch promptly from embryo development into germination. If ABA or water stress is responsible for preventing precocious germination, it may be that a high level of ABA is maintained or synthesized internally by embryonic axes of Phaseolus, while in other embryos the maternal environment supplies ABA and/or causes water stress.Abbreviations ABA Abscisic acid - BA benzyladenine     

An estrogen responsive primary amphibian liver cell culture system

Amphibian hepatocytes have been prepared in both high yield and purity using a collagenase perfusion technique. The isolated cells attach efficiently in serum-free medium to collagen-coated culture dishes and subsequently form monolayers. These cultures can be maintained in an appropriate medium for over one week with minimal cell loss. The nuclear labelling index of cells exposed to [³H]thymidine indicates a very low level of cell growth. Twenty-four hour exposure to dexamethasone induces tyrosine aminotransferase activity throughout the culture period. Monolayers incorporate [³H]leucine linearly into acid-insoluble material with approx. 40% of all synthesis devoted to secreted protein. Polyacrylamide gel electrophoresis of proteins in the presence of sodium dodecyl sulfate shows the majority of proteins present in whole serum are synthesized and secreted by the cultured hepatocytes. The absolute rate of protein secretion on the first day of culture is approx. 73 μg/day/mg cell protein which subsequently declines and plateaus at 30% of this level by the 4th–5th day of culture. However, when hepatocytes are cultured in the continued presence of insulin, the drop in protein secretion is completely inhibited.Cultures of hepatocytes isolated from female frogs and subsequently exposed to 17-B estradiol in culture, synthesize and secrete the egg-yolk protein precursor vitellogenin. The protein initially appears as a minor component in the medium 1–2 days after hormone addition. Its rate of synthesis, relative to other secreted proteins, increases with time so that it ultimately constitutes the majority of protein being exported after 6 days of treatment. Parallel with vitellogenin induction is an increase in rate of total protein secretion reaching a 2-fold increase at maximal stimulation.The results show that viable, monolayer cultures of amphibian hepatocytes can be prepared which retain the ability to respond directly to added estrogen by synthesizing vitellogenin.     

Reversible Repression of Early Enzyme Synthesis in Bacteriophage T4-infected Escherichia coli

A mutant of Escherichia coli B, defective in its accumulation of K⁺, was found to synthesize protein at a rate proportional to the level of this cation in the growth medium. When bacteriophage T4-infected cells were incubated in growth medium containing 1 mm K⁺, phage deoxyribonucleic acid (DNA) was synthesized at a rate 25% that of normal, and phage protein was synthesized at a rate of 50% of normal. Deoxycytidine pyrophosphatase, a phage-directed early enzyme, shut off at a level of 55% that of normal when infected cells were incubated in medium containing 1 mm K⁺. However, deoxycytidine pyrophosphatase synthesis resumed in these cells when they were shifted to medium containing the normal K⁺ concentration (33 mm). DNA synthesis also attained the rate characteristic of this K⁺ concentration. These results suggest that phage DNA synthesis is not sufficient to repress early protein formation and also indicate that the inhibitor of early protein formation is an early function whose synthesis is sensitive to the same repression as that of the early proteins.     

Mechanism of resistance to ricin toxin in selected mouse lymphoma cell lines

The role of impaired toxin uptake in conferring cellular resistance to the plant toxin RCA_II (ricin) has been examined using a murine BW5 147 lymphoma line and a toxin-resistant variant (BW5 147 Ric^R.3) selected by repeated exposure to RCA_II. The toxin-resistant variant is 250 times more resistant to RCA_II in long-term growth experiments and 1,000 times more resistant in short-term protein synthesis assays. Experiments with ferritin-conjugated ¹²⁵I-labeled RCA_II (ferritin-¹²⁵I-RCA_II) indicated that toxin binding to sensitive and resistant cells is similar at low toxin concentrations where maximum differential cytotoxicity occurs but that major difference exist with respect to toxin uptake. In sensitive cells toxin is internalized via endocytosis, and as seen previously in other systems subsequent rupture of some of the toxin-containing endocytotic vesicles releases toxin into the cytoplasm, where it inhibits protein synthesis. The process of toxin transfer to the cytoplasm is presumed to account for the one-hour lag before toxin-induced inhibition of protein synthesis can be detected. Endocytotic uptake of toxin is impaired in resistant BW5147Ric^R.3 cells, and they are unaffected by toxin concentrations that inhibit protein synthesis and kill sensitive parental cells. Killing of resistant cells at low toxin concentrations was accomplished by encapsulating RCA_II into lipid vesicles capable of fusing with the plasma membrane. Direct introduction of toxin into resistant cells using lipid vesicles as carriers produced rapid inhibition (< 15 min) of protein synthesis and eliminated the lag in toxin action seen in sensitive cells exposed to free toxin. These findings are discussed in relation to the mechanism of toxin action and proposals that toxin activity requires structural modification of the toxin molecule at the cell surface before transport into the cell.     

Uncoupling of RNA and DNA synthesis after plasma stimulation of G0-arrested BALB/C-3T3 cells.

The addition of whole serum to G0-arrested, confluent Balb/c-3T3 cells induces them to progress through G1 and synthesize DNA after a 12-h lag period. Prior to the onset of DNA synthesis, RNA is synthesized and RNA content increases. Serum has been fractionated into two sets of growth factors: a platelet-derived growth factor present in heat-treated (100 degrees C) platelet extracts and platelet-poor plasma. Addition of whole serum, platelet-derived growth factor or platelet-poor plasma induces quiescent cells to increase their cytoplasmic RNA content, but the cells treated with platelet-poor plasma do not synthesize DNA. Messenger RNA content increases within 2 h after stimulation with whole serum or platelet-poor plasma, and after 18 h, mRNA has accumulated to a greater degree than rRNA.     

Identification of the Products of Autonomous Mitochondrial Protein and Glycoprotein Synthesis

ISOLATED mitochondria synthesize proteins^1–3 and glycoproteins^3–6 independently but the percentage of the mitochondrial protein synthesized by the mitochondrion itself probably does not exceed 5% (ref. 3), the rest being synthesized on cytoribo-somes³. Mitochondrial structural protein was thought to be the product of mitochondrial protein synthesis, but this fraction is heterogeneous and contains denatured ATPase⁷. Nevertheless, multi-macromolecular fragments of mitochondria have been implicated as products of autonomous mitochondrial synthesis⁸.     

Synthesis of ferritin by neuroblastoma

Ferritin is an iron-containing protein which is a normal component of serum. The levels of ferritin are increased in the sera of some children with neuroblastoma, and this increase appears to be a potent indicator of prognosis. To determine whether synthesis of ferritin by the tumor cells contributes to these increased serum levels, we examined incorporation of radiolabeled leucine by CHP 126, a neuroblastoma derived cell line, into ferritin. Using sequential immunoprecipitation and gel electrophoresis of sonicates from cells maintained in medium containing iron in amounts standard for tissue culture, incorporation of label into ferritin was 0.04% of that into total protein synthesized over the same time period. Addition of up to 40 micrograms of iron as ferric ammonium citrate increased ferritin synthesis to a maximum of 0.16% without altering synthesis of total protein. The pattern of iron-induced enhancement in the neuroblastoma cells was similar to that which was seen using Chang liver cells, a cell line well known to be capable of ferritin synthesis. These results confirm that neuroblastoma cells can synthesize ferritin and that synthesis is regulated by exogenous iron.