Protein Synthesis in Euglena gracilis is Light-and Temperature-Dependent,Oscillating in a Circadian,Temperature-Compensated Manner

Abstract: Incorporation of radiolabelled amino acids into proteins of Euglena gracilis revealed that the amount of labelled protein depends on the conditions of illumination and temperature of cultivation. Protein synthesis was generally lower under dark conditions except at 37 °C. The largest amounts of labelled protein were measured at 21 °C and decreased at higher and lower temperatures. By separating the labelled proteins of the membraneous cell fraction from subcultures under a range of culture conditions, the synthesis of some specific proteins was found to be light- and/or temperature-dependent. On incubating cells taken at different times during a light/dark cycle and under constant conditions, a circadian rhythm of ³⁵S-methionine- as well as ³⁵S-cysteine-incorporation was detected. Thereby the cells incorporated ten-times less cysteine than methionine. Protein synthesis always peaked during the last quarter of the daily light phase, confirming the rhythmic rise in total protein. The length of the rhythm period, approximately 24 h, was nearly independent of the applied temperature in the range of 16 to 27 °C.     

Synthesis of soluble protein during the cell cycle of the fission yeast Schizosaccharomyces pombe

Many enzymes show a pattern of increase in activity through the cell cycle which is different from the continuous exponential pattern of total protein synthesis. A group of proteins at an intermediate level between single enzymes and total protein, the soluble proteins, was examined to resolve this anomaly. The synthesis of the pH 8.1 soluble proteins of Schizosaccharomyces pombe through the cell cycle was followed by pulse labelling with ³H-leucine in synchronous cultures. The soluble proteins were analysed by electrophoresis on acrylamide gels. Soluble proteins represent 30% of the total proteins of S. pombe and the rates of synthesis showed a continuous increase through the cell cycle. Individual groups of proteins, represented by a single band after electrophoresis, showed a similar continuous increase in synthesis through the cell cycle. Any proteins which may be synthesised discontinuously, such as some enzymes, represent such a small proportion of any one protein group in the electrophoretic separation that their effect was not detectable. These results are different from those described for mammalian cells.     

Synthesis of unique low molecular weight proteins during late G2 and mitosis

Changes in protein synthesis were examined during the cell cycle of Chinese hamster ovary cells by labeling synchronized cells at various times with [35S]methionine and separating the proteins on two-dimensional polyacrylamide gels. Several proteins, including tubulin, showed marked differences in their relative rates of synthesis during the cell cycle. A few proteins were found to be synthesized at a specific time during the cycle. In particular, a pair of proteins of approximately 21,000 daltons and isoelectric point of 5.5 were found to be synthesized only in late G2 and mitotic cells. Cells that were labeled during mitosis and then allowed to divide showed no trace of these proteins, indicating that their presence is transient and that they are likely involved in mitosis.     

Uptake of amino acids and thymidine during the first cell cycle of synchronized hamster cells.

The net total uptake of four amino acids (valine, leucine, lysine and methionine) used at concentrations required for growth, and of thymidine at tracer concentrations, has been studied during the first cell cycle of an asparagine-dependent strain of transformed BHK cells synchronized by asparagine starvation. The rate of the total uptake of the amino acids, the free pool of the amino acids taken up, and the rate of their incorporation into protein at the end of the first cell cycle were, on the average, 12-fold that at the beginning of the cell cycle. The increase in these parameters during the cell cycle was not linear. The uptake of thymidine started before the onset of DNA synthesis and proceeded linearly beyond the peak of the S phase. The rate of accumulation of thymidine into the acid-soluble fraction also increased during the S phase, apart from a tendency to plateau off at the peak of this phase. It reached a second plateau towards the end of the cell cycle, and then declined slightly. Evidence is presented which suggests that the total quantity of protein synthesized during the cell cycle is more than the newly synthesized protein present in the cells at the end of the cell cycle; this indicated degradation and/or secretion of a substantial proportion of the newly synthesized protein. The total protein synthesized at different time points in the cell cycle appeared to contain different proportions of the amino acids used.     

The cellular origin of glyoxysomal proteins in germinating castor-bean endosperm.

The capacity of castor-bean endosperm tissue to incorporate [35S]methionine into proteins of the total particulate fraction increased during the first 3 days of germination and subsequently declined. At the onset of germination 66% of the incorporated 35S was found in the separated endoplasmic-reticulum fraction, with the remainder in mitochondria, whereas at later developmental stages an increasing proportion of 35S was recovered in glyoxysomes. The kinetics of [35S]methionine incorporation into the major organelle fractions of 3-day-old endosperm tissue showed that the endoplasmic reticulum was immediately labelled, whereas a lag period preceded the labelling of mitochondria and glyoxysomes. When kinetic experiments were interrupted by the addition of an excess of unlabelled methionine, incorporation of [35S]methionine into the endoplasmic reticulum rapidly ceased, but incorporation into mitochondia and glyoxysomes continued for a further 1h. Examination of isolated organelle membranes during this period showed that the addition of unlabelled methionine resulted in a stimulated incorporation of [35S]no methionine into the endoplasmic-reticulum membrane for 30 min, after which time the 35S content of this fraction declined, whereas that of the glyoxysomal membranes continued to increase slowly. The 35S-labelling kinetics of organelles and fractions derived therefrom are discussed in relation to the role of the endoplasmic reticulum in protein synthesis during glyoxysome biogenesis.     

Uptake of amino acids and thymidine during the first cell cycle of synchronized hamster cells

Summary The net total uptake of four amino acids (valine, leucine, lysine and methionine) used at concentrations required for growth, and of thymidine at tracer concentrations, has been studied during the first cell cycle of an asparagine-dependent strain of transformed BHK cells synchronized by asparagine starvation. The rate of the total uptake of the amino acids, the free pool of the amino acids taken up, and the rate of their incorporation into protein at the cell cycle. The increase in these parameters during the cell cycle was not linear. The uptake of thymidine started before the onset of DNA synthesis and proceeded linearly beyond the peak of the S phase. The rate of accumulation of thymidine into the acid-soluble fraction also increased during the S phase, apart from a tendency to plateau off at the peak of this phase. It reached a second plateau towards the end of the cell cycle, and then declined slightly. Evidence is presented which suggests that the total quantity of protein synthesized during the cell cycle is more than the newly synthesized protein present in the cells at the end of the cell cycle; this indicates degradation and/or secretion of a substantial proportion of the newly synthesized protein. The total protein synthesized at different time points in the cell cycle appeared to contain different proportions of the amino acids used.     

Patterns of protein synthesis during the cell cycle of Chinese hamster ovary cells

The protein synthesis patterns at various stages of the cell cycle of Chinese hamster ovary cells were examined by labelling cells with [35S]methionine and then separating the proteins by isoelectric focussing and two-dimensional, nonequilibrium pH gradient gel electrophoresis. We have observed a number of proteins which display quantitative differences in synthesis at specific cell cycle stages and of these the alpha- and beta-tubulins have been identified. A few proteins appear to be uniquely synthesized at specific times during the cell cycle. These include the histones and a modified version of them, which are synthesized only in S phase, and a pair of 21 kilodalton (kDa), pI 5.5 proteins, which appear only in late G2 and mitosis. We have also identified a 58-kDa, pI 7.5 protein which is present at all cell cycle stages except during late G2. This protein appears to have the same temporal properties as a 57-kDa protein called "cyclin" originally described in sea urchin embryos.     

Cycles of protein synthesis during pupal diapause in the flesh fly,Sarcophaga crassipalpis

Protein synthesis is cyclic during pupal diapause in Sarcophaga crassipalpis. These cycles are in phase with infradian MO₂ cycles, which have a periodicity of about 4 days at 25°C. Mean incorporation of [³⁵S]methionine by diapausing pupae was 5.4% during the 2 days of highest MO₂ but dropped to 1.7% during the 2 days of low MO₂. Diapausing pupae treated with a juvenile hormone analog prior to pupariation had a constant high MO₂ similar to peak values observed in untreated pupae, and such pupae consistently incorporated [³⁵S]methionine at a high rate (7.7%). [³⁵S]Methionine incorporation by nondiapausing pupae and pharate adults was eightfold higher than the peak rates observed during diapause. Autoradiography of in vivo labeled proteins indicated quantitative and qualitative changes in the synthesis of proteins by diapausing pupae during different phases of the MO₂ cycle. Brains from diapausing pupae labeled in vitro showed higher incorporation at the peak of the MO₂ cycle than at the nadir of the cycle, but no such differences were detected for integument, fat body, or fat body supernatant. Theses differences in tissue response indicate that control of protein synthesis during diapause is not cell autonomous, but is a function of the metabolism of the intact organism.     

Leucine incorporation and its potential as a measure of protein synthesis by bacteria in natural aquatic systems

Leucine incorporation was examined as a method for estimating rates of protein synthesis by bacterial assemblages in natural aquatic systems. The proportion of the total bacterial population that took up leucine in three marine environments was high (greater than 50%). Most of the leucine (greater than 90%) taken up was incorporated into protein, and little (less than 20%) was degraded to other amino acids, except in two oligotrophic marine environments. In samples from these two environments, ca. 50% of the leucine incorporated had been degraded to other amino acids, which were subsequently incorporated into protein. The degree of leucine degradation appears to depend on the organic carbon supply, as the proportion of 3H-radioactivity incorporated into protein that was recovered as [3H]leucine after acid hydrolysis increased with the addition of pyruvate to oligotrophic water samples. The addition of extracellular leucine inhibited total incorporation of [14C]pyruvate (a precursor for leucine biosynthesis) into protein. Furthermore, the proportion of [14C]pyruvate incorporation into protein that was recovered as [14C]leucine decreased with the addition of extracellular leucine. These results show that the addition of extracellular leucine inhibits leucine biosynthesis by marine bacterial assemblages. The molar fraction of leucine in a wide variety of proteins is constant, indicating that changes in leucine incorporation rates reflect changes in rates of protein synthesis rather than changes in the leucine content of proteins. The results demonstrate that the incorporation rate of [3H]leucine into a hot trichloroacetic acid-insoluble cell fraction can serve as an index of protein synthesis by bacterial assemblages in aquatic systems.     

Translational capacity of sheep oocytes microinjected with messenger RNA

Sheep oocytes were microinjected with tobacco mosaic virus RNA (TMV-RNA) and isotopically labelled with L-[35S]methionine. Total incorporation of labelled methionine was similar in TMV-RNA-injected and in carrier-injected control oocytes, whether injections were performed during the period of high protein synthesis at maturation or during the period of reduced synthesis at a time equivalent to the mid-cleavage transition (48 h after germinal vesicle breakdown). Varying the amount of TMV-RNA injected from 2.5 to 10 pg had little effect on the overall level of amino acid incorporation. Furthermore TMV-RNA appeared to be very stable in oocytes and eggs; the proportion of total polypeptide synthesis directed by TMV-RNA did not diminish during the first 48 h after injection. Synthesis of most endogenous proteins was uniformly reduced to compensate for the synthesis of TMV-polypeptides. Our results suggest, therefore, that the translational capacity of sheep oocytes is fully saturated during maturation.     

Leucine incorporation and its potential as a measure of protein synthesis by bacteria in natural aquatic systems.

Leucine incorporation was examined as a method for estimating rates of protein synthesis by bacterial assemblages in natural aquatic systems. The proportion of the total bacterial population that took up leucine in three marine environments was high (greater than 50%). Most of the leucine (greater than 90%) taken up was incorporated into protein, and little (less than 20%) was degraded to other amino acids, except in two oligotrophic marine environments. In samples from these two environments, ca. 50% of the leucine incorporated had been degraded to other amino acids, which were subsequently incorporated into protein. The degree of leucine degradation appears to depend on the organic carbon supply, as the proportion of 3H-radioactivity incorporated into protein that was recovered as [3H]leucine after acid hydrolysis increased with the addition of pyruvate to oligotrophic water samples. The addition of extracellular leucine inhibited total incorporation of [14C]pyruvate (a precursor for leucine biosynthesis) into protein. Furthermore, the proportion of [14C]pyruvate incorporation into protein that was recovered as [14C]leucine decreased with the addition of extracellular leucine. These results show that the addition of extracellular leucine inhibits leucine biosynthesis by marine bacterial assemblages. The molar fraction of leucine in a wide variety of proteins is constant, indicating that changes in leucine incorporation rates reflect changes in rates of protein synthesis rather than changes in the leucine content of proteins. The results demonstrate that the incorporation rate of [3H]leucine into a hot trichloroacetic acid-insoluble cell fraction can serve as an index of protein synthesis by bacterial assemblages in aquatic systems.     

Regulation of cell-cycle initiation in yeast by nutrients and protein synthesis.

Arrested Saccharomyces cerevisiae cells initiate the cell cycle in an asynchronous mode. The asynchronous manner of cycle initiation generates variability in cell-cycle times of individual cells. Limiting concentrations of adenine, methionine or histidine regulate the rate of cycle initiation in auxotrophs. A sigmoidal curve of rate vs. concentration is obtained for each of the three substances. Moreover, the three curves have similar Hill coefficients of 2.4, suggesting that a common intermediate requiring adenine, methionine and histidine regulates cell-cycle initiation in yeast. Low concentrations of cycloheximide reduce the rate of cycle initiation of arrested cells that are released from the block in a similar way as limiting nutrients. It thus appears that the common intermediate that requires the limiting nutrients depends upon protein synthesis. The rate of cycle initiation is more sensitive to cycloheximide or nutrient limitation than is protein synthesis. It is also affected by limiting nutrients to a much greater extent than is the overall rate of protein accumulation (i.e., net protein synthesis). Hence the mechanism that controls cycle initiation does not depend on the overall synthesis or accumulation of proteins in the cell. It may depend on synthesis of particular proteins whose production or function requires the limiting nutrients. The high sensitivity of cycle initiation to a decrease in the rate of protein synthesis could explain the ability of yeast cells to complete the cycle and arrest at stationary phase upon depletion of medium components. The cells cannot initiate the cycle although their protein synthesis capacity remains sufficiently high to allow traversal of the rest of the cell cycle.     

Biosynthesis of tissue inhibitor of metalloproteinases by human fibroblasts in culture. Stimulation by 12-O-tetradecanoylphorbol 13-acetate and interleukin 1 in parallel with collagenase

Biosynthesis of the glycoprotein tissue inhibitor of metalloproteinases (TIMP) by human fibroblasts in culture has been characterized by functional assays, immunoprecipitation, and immunocytochemistry with a monospecific antiserum. As determined by radiolabeling with [35S]methionine, immunoprecipitation, and analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the secreted form of TIMP had an Mr of 29,000, whereas the form associated with the cell layer had an Mr of 24,000. Unstimulated human lung fibroblasts (HFL-1) secreted TIMP at the rate of approximately 2 micrograms/10(6) cells/24 h, and normal foreskin fibroblasts (HS 27) and skin fibroblasts from a patient with Hurler's disease (GM 1391) secreted TIMP at 0.3 and 0.2 micrograms/10(6) cells/24 h, respectively. Secretion of TIMP was stimulated up to 10-fold by treating the cells with 20-100 ng/ml of 12-O-tetradecanoylphorbol 13-acetate or 10 units/ml of human interleukin 1. In the stimulated HFL-1 cells, TIMP accounted for 0.03-0.09% of the total [35S]methionine incorporated into protein, and 0.3-0.8% of the [35S]methionine in secreted protein. Although TIMP accounted for a relatively small proportion of total protein synthesis of the fibroblasts, greater than 80% of untreated and greater than 95% of stimulated fibroblasts synthesized TIMP, as determined by indirect immunofluorescence. The treatments of the human fibroblasts that increased TIMP secretion also induced synthesis and secretion of proenzyme forms of collagenase, indicating that degradative enzymes and their controlling inhibitors may be synthesized in parallel under certain conditions.     

Phospholipid Metabolism in Mouse Sciatic Nerve In Vivo

To probe the activities of various pathways of lipid metabolism in peripheral nerve, six phospholipid-directed precursors were individually injected into the exposed sciatic nerves of adult mice, and their incorporation into phospholipids and proteins was studied over a 2-week period. Tritiated choline, inositol, ethanolamine, serine, and glycerol were mainly used in phospholipid synthesis; in contrast, methyl-labeled methionine was primarily incorporated into protein. Phosphatidylcholine was the main lipid formed from tritiated choline, glycerol, and methionine precursors. Phosphatidylserine, phosphatidylethanolamine, and phosphatidylinositol were the main lipids formed from serine, ethanolamine, and inositol, respectively. With time there was a shift in label among phospholipids, with higher proportions of choline appearing in sphingomyelin, glycerol in phosphatidylserine, ethanolamine in phosphatidylethanolamine (plasmalogen), and inositol in polyphosphoinositides, especially phosphatidylinositol 4,5-bisphosphate. We suggest that the delay in formation of these phospholipids, which are concentrated in peripheral nerve myelin, may, at least in part, be due to their formation at a site(s) distant from the sites where the bulk of Schwann cell lipids are made. We propose that separating the synthesis of these myelin-destined lipids to near the Schwann cell's plasma membrane would facilitate their concentration in peripheral nerve myelin sheaths. At earlier labeling times, ethanolamine and glycerol were more actively incorporated into phosphatidylcholine and phosphatidylinositol, respectively, than later. The transient labeling of these phospholipids may reflect some unique role in peripheral nerve function.     

Diel rhythmicity in amino acid uptake by Prochlorococcus

The marine cyanobacterium Prochlorococcus , the most abundant phototrophic organism on Earth, numerically dominates the phytoplankton in nitrogen (N)-depleted oceanic gyres. Alongside inorganic N sources such as nitrite and ammonium, natural populations of this genus also acquire organic N, specifically amino acids. Here, we investigated using isotopic tracer and flow cytometric cell sorting techniques whether amino acid uptake by Prochlorococcus is subject to a diel rhythmicity, and if so, whether this was linked to a specific cell cycle stage. We observed, in contrast to diurnally similar methionine uptake rates by Synechococcus cells, obvious diurnal rhythms in methionine uptake by Prochlorococcus cells in the tropical Atlantic. These rhythms were confirmed using reproducible cyclostat experiments with a light-synchronized axenic Prochlorococcus (PCC9511 strain) culture and ³⁵S-methionine and ³H-leucine tracers. Cells acquired the tracers at lower rates around dawn and higher rates around dusk despite >10⁴ times higher concentration of ammonium in the medium, presumably because amino acids can be directly incorporated into protein. Leucine uptake rates by cells in the S+G₂ cell cycle stage were consistently 2.2 times higher than those of cells at the G₁ stage. Furthermore, S+G₂ cells upregulated amino acid uptake 3.5 times from dawn to dusk to boost protein synthesis prior to cell division. Because Prochlorococcus populations can account from 13% at midday to 42% at dusk of total microbial uptake of methionine and probably of other amino acids in N-depleted oceanic waters, this genus exerts diurnally variable, strong competitive pressure on other bacterioplankton populations.     

Protein synthesis in salivary glands of Drosophila melanogaster: relation to chromosome puffs

The salivary glands and other tissues from Drosophila melanogaster were dissected at various times throughout the prepupal period, as well as after heat shocks and ecdysterone treatments, and the proteins labelled by incubating the isolated tissues with [³⁵S]methionine were separated by electrophoresis on sodium dodecyl sulphate-polyacrylamide gel. The labelled band patterns from salivary gland, as seen on the autoradiograph of the gel, showed striking variations, in a manner remarkably similar to variations in puff patterns during the same prepupal period. In proteins from Malpighian tubes, the pattern of bands varied to a lesser extent and in brain only a few components were modified.Heat shock brought about the appearance of a number of new bands, while others were reduced in intensity. This effect was observed with all the tissues examined, salivary glands, brain and Malpighian tubes, as well as wing imaginal discs, tissue lacking polytene chromosomes. The six most heavily labelled bands induced by heat shock represent about 30%, and one component alone represents over 15%, of the total label in the sample, as seen in salivary glands, brain and Malpighian tubes. The synthesis of RNA at puff sites was investigated after heat shock by [³H]uridine labelling. By correlating the amount of [³H]uridine in some puffs with the level of [³⁵S]methionine in some bands a tentative relation is suggested in a few instances.The effect of ecdysterone treatment was also studied in the salivary glands. Changes in a number of protein bands were noticed, though they were much less pronounced than those following heat shock.     

Protein synthesis in lactating guinea-pig mammary tissue perfused in vitro. I. Radiolabelling of membrane and secretory proteins

A method for the in vitro perfusion of isolated guinea-pig mammary tissue is described that allows the radiolabelling of secretory and membrane proteins. Glands were depleted of methionine, labelled with [35S]methionine for 5 min and perfused with medium containing an excess of unlabelled methionine for varying times. The structural integrity of the alveoli in the perfused glands appeared well maintained. Epithelial polarity was preserved and junctional complexes were evident. About 20% of the methionine provided in the medium was extracted by glands of 10 g wet weight under the labelling conditions employed. With chase periods from 15 to 40 min, 50-70% of the methionine was incorporated into trichloroacetic-acid (TCA)-precipitable material. The principal radiolabelled proteins recovered from the tissue fractions had Mrs and isoelectric points similar to the major secretory proteins (i.e. caseins and alpha-lactalbumin) of guinea-pig milk. Autoradiography of tissue sections at the resolution of the light microscope showed that secretory proteins were transported from sites of synthesis within secretory cells to the alveolar lumina after 45 min. These highly labelled secretory proteins could be almost completely removed from microsomal fractions by treatment with sodium carbonate solutions. Proteins with Mrs from 30 000 to 200 000 were detected in the washed membranes by SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and fluorography. These labelled membrane-associated proteins persisted in the microsomal membrane fraction after chase periods from 7.5 to 40 min.     

Stage-specific synthesis and fucosylation of plasma membrane proteins by mouse pachytene spermatocytes and round spermatids in culture

Little is known about the ability of mammalian spermatogenic cells to synthesize plasma membrane components in the presence or absence of Sertoli cells. In this study, purified populations (greater than 90%) of pachytene spermatocytes or round spermatids were isolated by unit gravity sedimentation and cultured for 20-24 h in the presence of [35S]methionine or [3H]fucose. Cell viabilities remained over 90% during the course of these experiments. Plasma membranes were purified from these cells and analyzed by two-dimensional gel electrophoresis. Qualitatively, the same plasma membrane proteins were synthesized by both cell types with the exception of the major Concanavalin A-binding glycoprotein, p151; the synthesis of p151 is greatly diminished or inhibited after meiosis. [3H]Fucose was incorporated into at least 6 common glycoproteins of both cells. Eight components fucosylated with molecular weights from 35,000 to 120,000 were specific to pachytene spermatocyte membranes. One fast-migrating fucosylated component may represent an uncharacterized lipid whose synthesis is terminated after meiosis. Round spermatids specifically fucosylated two components with molecular weights of 45,000 and 80,000. These results demonstrate the viability of germ cells of the male mouse in short-term culture and show that they are capable of synthesizing and fucosylating plasma membrane components in the absence of Sertoli cells.