The termination of the synthesis of proteins in vitro with extracts from the undeveloped cyst of Artemia salina

Soluble fractions (S-100) from both undeveloped cysts and developing embryos of Artemia salina promoted elongation of polypeptides initiated in vivo on polysomes of developing embryos or nauplius larvae. The ability of the extract from the undeveloped cyst to terminate correctly the synthesis of polypeptides has been determined indirectly from the distribution of polysomes before and after in vitro translation and, more directly, from the nature of the protein product released from rabbit reticulocyte polysomes. The extract from the undeveloped cyst and also, as expected, that from the developing embryo catalyzed a reduction in the amount of the polysomes of larger size and an increase in the amount of 80 S ribosomes. The soluble extract from the undeveloped cyst can terminate the synthesis of rabbit globin on reticulocyte polysomes. The major polypeptide product released from the polysomes had an electrophoretic mobility identical with that of the subunit of isolated rabbit globin. This indicated that the cyst contained the components necessary to complete and terminate the synthesis of polypeptides correctly and that the released protein product was not predominantly as a result of premature chain termination. The size distribution of Artemia salina proteins released from polysomes from developing embryos was similar when the synthesis was directed by the S-100 at each stage of development.     

Translational alterations in maize leaves responding to pathogen infection, paraquat treatment, or heat shock : polysome dissociation and accumulation of a 57 kilodalton protein

Translational alterations occur in maize (Zea mays L.) leaves stressed by pathogen infection or herbicide paraquat treatment. These translational changes include: (a) dissociation of large polysomes to small polysomes, monosomes, and subunits; (b) a decreased rate of total protein synthesis; and (c) a reduced synthesis of several proteins by polysomes in vitro. The polysome dissociation was neither due to an extraction artifact nor to degradation of RNA by RNase. The protein patterns of polysomes isolated from leaves inoculated with Bipolaris maydis at 6 to 48 hours showed an increase in the intensity of a 57 kilodalton protein. When inoculated with less virulent pathogens, such as B. zeicola, Exserohilum turcicum, or Colletotrichum graminicola, the protein was accumulated in polysomes of leaves at 24 to 48 hours after inoculation. The 57 kilodalton protein was also accumulated in polysomes of maize leaves responding to heat shock or herbicide paraquat treatments. The purified 57 kilodalton protein reassociated with polysomes isolated from healthy leaves and inhibited polysomal translation in vitro. Since the 57 kilodalton protein is rapidly accumulated in maize polysomes in response to various biological and environmental stresses and may affect protein synthesis, it may be involved in translational regulation of maize leaves during stress response.     

Patterns of urease synthesis in developing soybeans

An examination of in vivo polysome-bound activity indicates that soybean (Glycine max, cv. Prize) seed urease is synthesized on large polysomes (n ≥ 15). In vitro urease synthesis is directed by a large RNA (3,000-3,300 nucleotides). Urease synthesis occurs throughout the normal protein biosynthetic phase of the developing seed. Surprisingly, the activity/antigen ratios of urease increase throughout development. Urease appears to be in a more highly polymerized state in mature beans versus beans in early development.     

Ribonucleic Acid and Protein Metabolism in Pea Epicotyls : III. Response to Auxin in Aged Tissue

Applications of auxin to the tips of intact aged pea Pisum sativum L. var Alaska epicotyls resulted in an increase in the content of polyribosomes and poly(A) and in the capacity of isolated polysomes to support protein synthesis in vitro. Few changes were seen in the two-dimensional gel patterns of silver-stained proteins accumulated (or degraded) in vivo even after 15 hours of auxin treatment. In contrast, substantial changes were evident in the two-dimensional gel fluorographs of polypeptides generated in vitro by total RNA and by polysomal RNA from tissue treated with auxin for only 6 hours. Of the 200 spots resolved by fluorography, total RNA from auxin-treated tissue generated 33 spots with increased intensity and 10 with decreased intensity; polysomal RNA yielded 33 spots which increased and only three that decreased. In general, the polypeptides that increased in intensity were higher molecular weight and those that decreased were lower molecular weight. These changes occurred prior to growth and might be prerequisite for the auxin-induced slow growth response seen in this aged tissue.     

Role of endoplasmic reticulum in biosynthesis of oat globulin precursors

Oat (Avena sativa L.) groats were labeled with radioactive leucine and salt-soluble proteins were extracted and analyzed. Polyacrylamide gel electrophoresis followed by fluorography indicated two radioactive polypeptides with molecular weight 58 to 62 kilodaltons which were similar in size to unreduced globulin α-β dimers. The role of endoplasmic reticulum in the synthesis of these globulin polypeptides was investigated by in vivo and in vitro protein synthesis studies. Labeled tissue was fractionated by centrifugation and rough endoplasmic reticulum was isolated. Two polypeptides which had molecular weights of 58 to 62 kilodaltons and were immunoprecipitable with antiglobulin immunoglobulin G were found to be transiently associated with the endoplasmic reticulum. Rough endoplasmic reticulum, as well as membrane-bound polysomes, directed the in vitro synthesis of two polypeptides with molecular weight 58 to 62 kilodaltons corresponding in size to unreduced α-β dimers and could be immunoprecipitated with antiglobulin immunoglobulin G. The translation products of free polysomes did not show this. In pulse-labeling, globulin polypeptides with molecular weight 58 to 62 kilodaltons, as well as the α + β subunits, were labeled in protein bodies.

The data suggest that oat globulin polypeptides are synthesized as higher molecular weight precursors on ER-associated polysomes. These precursors are probably transported into protein bodies and cleaved into smaller α and β subunits.

     

Wounding of Aged Pea Epicotyls Enhances the Reinitiating Ability of Isolated Ribosomes

Total ribosomes (monosomes plus polysomes) isolated from woundedpea epicotyls are more efficient at supporting protein synthesisin a wheat germ S₃₀ system (containing wheat ribosomes) thanare total ribosomes from aged (control) pea tissue. This increasedefficiency is seen when enriched large polysomes, almost devoidof monosomes, are used to program a wheat germ S₃₀₀ system,from which the wheat germ ribosomes have been removed. Reactionsprimed by enriched polysomes from wounded tissue, but not agedtissue, continue for at least 30 min, suggesting that reinitiationis occurring during the reaction, albeit in the initial absenceof monosomes from wheat or pea. Wheat germ ribosomes, but notmonosomes from either aged or wounded pea tissue, are able totranslate pea poly(A) RNA and globin mRNA. Aurintricarboxylicacid reduces protein synthesis in a rather indiscriminate manner,whereas, pactamycin seems to have an inhibitory effect specificfor initiation, and it is much more effective on wounded thanon control tissue polysomes. We interpret these results to implythat polysomal ribosomes from wounded tissue are more efficientat initiation than are polysomal ribosomes from control tissueor than non-polysomal ribosomes (monosomes) from either tissue. (Received May 7, 1985; Accepted July 4, 1985)     

Comparison between wheat embryos isolated mechanically and by floating off from organic solvents

Wheat embryos floated off from organic solvents have been compared with mechanically isolated embryos. The results of comparative investigations, including germination,in vivo formation of polysomes and efficiency of cell free preparations forin vitro protein synthesis, favour the use of floated embryos for studies of biochemical processes during germination.     

Effects of juvenile hormone on polysome integrity

Juvenile hormone inhibits protein and RNA synthesis in cell cultures from Trichoplusia ni and in the testicular germinal cysts of Hyalophora cecropia pupae in vitro. Sucrose gradient analyses revealed that the polysomes of both the T. ni cells and the germinal cysts were disaggregated almost immediately after the addition of juvenile hormone in vitro with a corresponding dose-dependent increase in monosomes. It is suggested that previous reports revealing juvenile hormone inhibition of ecdysone stimulated RNA and protein synthesis may be due to polysome disaggregation. Further studies demonstrated that the effect is not restricted to insect cells and can be elicited by several other lipids devoid of juvenile hormone morphogenetic activity. Experiments with broken cell preparations and isolated polysomes suggest the necessity of cell membrane integrity for the effect on the polysomes. Several probing studies utilizing cycloheximide, ribonuclease, and high K⁺ concentrations were conducted on the means by which juvenile hormone and other lipids may elicit polysome disaggregation.     

Isolation and characterization of ribosomes from thoraces of the sheep blowfly,Lucilia cuprina,and their capacity for protein synthesis at different stages of development

The isolation and characterization of ribosomal fractions from thoraces of Lucilia cuprina have been described and their capacity for in vitro protein synthesis studied at different stages of development. There are large differences in the yield of ribosomes during development, and these probably reflect differences in the number of ribosomes in vivo. The amino acid incorporation activity varied at different stages of development and this variation correlated with the percentage of polysomes present. Maximal activity was found just after adult emergence. Results obtained by the use of supernatant fractions from different stages of development suggest that control of protein synthesis in this insect takes place at the level of translation.     

Plant Desiccation and Protein Synthesis: II. On the Relationship between Endogenous Adenosine Triphosphate Levels and Protein-synthesizing Capacity

Rehydration of Tortula ruralis in 2,4-dinitrophenol inhibits protein synthesis, polysome formation, and ATP production. Polysomes are conserved intact and are active in vitro in hydrated Tortula placed in this chemical, although in vivo protein synthesis is inhibited. Hydrated moss placed under nitrogen in the dark shows a reduced capacity for ATP and protein synthesis, but polysomes are conserved. During anaerobiosis in light, ATP and protein synthesis are unaffected. Rehydration of slow-dried Tortula in nitrogen in the dark results in reduced in vivo protein synthesis, but not polysome formation; this reduction is much less in the light. Slow-dried moss, but not fast-dried, has a greatly reduced ATP content in the dry state, but this rapidly returns to normal levels on rehydration. The prolonged burst in respiration observed previously on rehydration of Tortula is not paralleled by ATP accumulation. Changes in energy charge in all treatments tested follow the changes in ATP. The aquatic moss, Hygrohypnum luridum, which is intolerant to drought, loses ATP during fast drying and this is not replenished on subsequent rehydration.     

Plant Desiccation and Protein Synthesis : VI. Changes in Protein Synthesis Elicited by Desiccation of the Moss Tortula ruralis are Effected at the Translational Level

Upon rehydration of the moss Tortula ruralis following desiccation at a rapid or slow rate, there is increasing utilization of newly synthesized-poly(A)⁺ RNA for protein synthesis. Initially, poly(A)⁺ RNA conserved in the dry moss is associated with polysomes, but by 2 hours of rehydration there is an overwhelming recruitment of newly synthesized poly(A)⁺ RNA, at the expense of conserved messages. In rehydrated moss, there is a marked synthesis in vivo of new proteins, which are separable by two-dimensional electrophoresis, and identifiable by fluorography. These new proteins, termed rehydration proteins, are synthesized after both rapid and slow desiccation, but their synthesis persists longer after rapid desiccation. The protein patterns obtained following in vitro translation of bulk RNA from hydrated, desiccated, and rehydrated moss were qualitatively identical. Thus the differences in protein patterns observed in vivo must result from preferential selection of specific mRNAs from the same pool, which is indicative of control of protein synthesis at the translational level. The implications of these observations in relation to the response of the moss to drying in its natural environment are discussed.     

Specific protein synthesis in isolated epithelium of guinea-pig seminal vesicle. Effects of castration and androgen replacement

Four intrinsic soluble secretory proteins are synthesized in vitro by isolated seminal-vesicle mucosa from sexually mature guinea pigs. Newly synthesized specific proteins labelled with [¹⁴C]glycine and [¹⁴C]lysine were precipitated by using double-antibody immunoprecipitation techniques and their radioactivity was assessed. Rates of synthesis were determined on each of 5 days after castration. By 5 days after castration the wet weight of the epithelium decreased to 42% of intact control values; the absolute amount of specific protein synthesized in vitro after 60min incubation decreased to 28% and the 27500g cytoplasmic protein content decreased to 31%. Thus androgen deprivation leads to a decrease in general protein synthesis in vivo, as well as to a decrease in specific protein synthesis in vitro. Specific protein synthesis comprised 76% of the total protein formed in isolated tissue from animals 5 days after castration as compared with 99–100% in tissue from intact animals. At 72h after an injection of testosterone or dihydrotestosterone, seminal-vesicle epithelium wet weight, cytoplasmic protein content and capability for synthesizing specific proteins in vitro were restored to approx. 70% of normal values. At 72h after onset of therapy with 3α-androstanediol, both epithelium wet weight and cytoplasmic protein content had increased significantly, but without a corresponding increase in the capability of the isolated tissue to synthesize specific proteins. The soluble labelled proteins synthesized in vitro by isolated epithelium from intact animals during 60 or 120min incubation were essentially entirely immunoprecipitable, i.e. specific. In contrast, approx. 29% of all soluble protein newly synthesized by isolated epithelium from animals 5 days after castration was acid-precipitable, but not immunoprecipitable, i.e. `non-specific'. The injection of testosterone into castrated animals inhibited the synthesis of the non-specific fraction by isolated tissue. The effects of castration on the ultrastructure of guinea-pig seminal-vesicle epithelium are also presented.     

Glycosylation of nascent polypeptide chains in Aspergillus niger

Polysomes were isolated from Aspergillus niger and were characterized on sucrose gradients in several ways. First, they were found to be susceptible to degradation by treatment with RNase or EDTA. Second, they were labeled after treating mycelia with short pulses of [³H]uridine or [³H]leucine prior to polysome isolation. Third, they were capable of stimulating incorporation of [³H]leucine into trichloroacetic acid-precipitable material in a chick reticulocyte cell-free protein-synthesizing system. When isolated [³H]leucine pulse-labeled polysomes were treated with either EDTA-RNase or puromycin, 80–90% of the radioactivity was released, indicating that only the nascent polypeptide chains were labeled. After exposing mycelia for 1 min to [¹⁴C]mannose, the polysomes were exclusively labeled, indicating that initial glycosylation takes place on nascent polypeptide chains. Preincubation of mycelia with 2-deoxyglucose followed by pulse-labeling with [³H]leucine and [¹⁴C]mannose showed that 2-deoxy-d-glucose inhibits both protein synthesis and glycosylation. However, similar preincubation with tunicamycin caused an 80% drop in [¹⁴C]mannose label in the polysomes, but only a 10–20% drop of [³H]leucine label, suggesting that glycosylation of nascent chains in A. niger involves an oligosaccharide-lipid intermediate, since it has been shown that tunicamycin inhibits the synthesis of such an intermediate. When isolated polysomes were placed into an in vitro glycosylating mixture containing Mn²⁺, GDP-[¹⁴C]mannose, and smooth membranes from A. niger nascent chains were labeled. This reaction was shown to be dependent on addition of polysomes to the mixture and was not inhibited by 2-deoxy-d-glucose or tunicamycin. Both in vivo and in vitro glycosylated nascent chains were found to have about the same size range, and so it is suggested that in vitro no new oligosaccharide chains were synthesized, but preexisting chains were extended.     

Regulation of nitrite reductase : cell-free translation and processing

A protein with molecular mass of 67 kilodaltons is immunoprecipitated from in vitro translated products obtained from rabbit reticulocyte lysate primed with polyadenylated RNA from nitrate treated illuminated pea seedlings. This protein resembles the native nitrite reductase because of its competitive elimination when immunoprecipitation of in vitro translated products was carried out in the presence of cold unlabeled nitrite reductase or in vivo labeled pea leaf extract. This protein is of slightly higher molecular weight than that of the native nitrite reductase. Proteinaceous extracts from chloroplasts convert the in vitro product to the same molecular weight as the native peptide. The conversion appears to occur in two steps. Polyadenylated RNA from nitrate deficient plants or from nitrate-treated plants transferred to darkness do not support the synthesis of nitrite reductase. It is concluded that nitrate and light modulate the synthesis of the enzyme nitrite reductase by regulating the availability of mRNA for the enzyme.     

Elongation and termination reactions of protein synthesis on maize root tip polyribosomes studied in a homologous cell-free system

We show that the control of gene expression at the level of elongation and termination of protein synthesis can be observed in vitro. Free cytoplasmic polyribosomes were isolated from maize (Zea mays) root tips, and translated in root tip extracts that had been fractionated with ammonium sulfate to contain elongation factors, and be depleted in initiation factors. The root tip extract performs elongation and termination reactions as efficiently as wheat germ extracts. The translation products of the maize system are the same as made in vivo. The dependence of these in vitro elongation and termination reactions on pH was determined. Total protein synthesis in this system exhibits an optimum at pH ~7.5. However, the pH dependence of rates of synthesis of individual proteins is not at all uniform; many polyribosomes become stalled when translated at low pH. These data were compared with the elongation and termination capacity of polyribosomes isolated from oxygenated and hypoxic root tips (tissue having, respectively, high and low cytoplasmic pH values). We observed an inverse relationship between the relative abundance of many specific translatable mRNAs in polyribosomes of hypoxic root tips, and the relative rates of elongation and termination reactions on the different mRNAs at low pH in vitro. These results suggest that changes in intracellular pH in hypoxic root tips can be sensed directly by the translational machinery and thereby selectively modulate gene expression.     

Hormonal regulation of epidermis-specific protein and messenger RNA synthesis in amphibian metamorphosis

Experiments using a monospecific antibody directed against one type of epidermis-specific keratin from adult skin of the amphibian Xenopus laevis have demonstrated that polysomes synthesizing this protein first appear within larval skin during natural metamorphosis. Further experiments demonstrated that the synthesis of keratin within larval skin could be induced precociously by the thyroid hormone, 3,3′,5-triiodo-l-thyronine, both in vivo and when the isolated larval skin is cultured in vitro. The earliest developmental age responsive to such hormone induction appeared to be Stage $\text{50}\text{52}$ of larval development. This is about 20–24 days before keratin would normally make its appearance within the skin during natural metamorphosis. Hormone treatment of tadpoles at this age will also cause a precocious increase in the amount of keratin messenger RNA present within larval skin. This has been demonstrated directly by the isolation of poly(A)-containing messenger RNA from hormone-treated larvae and its translation in a wheat germ cell-free system to give immunoprecipitable keratin. Peptide analysis of the in vitro translation product indicates that the hormone-induced mRNA probably codes for an initial protein product that is slightly larger than keratin itself.     

Movement of ribosomes over messenger RNA in polysomes of rel + and rel - Escherichia coli strains

The in vitro movement of ribosomes over messenger RNA was studied in both the presence and the absence of protein synthesis. For this purpose, labeled polysomes were extracted from rel⁺ and rel^? strains of Escherichia coli grown in the presence of radioactive uracil and incubated in a cell-free system containing tRNA, amino acids, soluble enzymes and a source of energy. The gradual conversion of the labeled polysomes into monosomes and ribosomal subunits was followed by subjecting the reaction mixture to sucrose gradient sedimentation after various incubation times and measuring the radioactivity present in the three relevant ribosomal fractions.It was found that when the conditions of incubation allow protein synthesis to occur, polysomes extracted from rel⁺ and rel^? cells are converted mainly into free monosomes, which can be made to dissociate into subunits by high-sodium or low-magnesium ion concentrations. Under conditions in which protein synthesis cannot occur because a mutant aminoacyl-tRNA synthetase has been rendered inactive, polysome conversion still occurs, though to a reduced extent. When the products of such residual run-off are examined, however, a difference is manifest between polysomes extracted from rel⁺ and from rel^? strains: whereas the polysomes from the rel^? strain are still converted into free monosomes even in the absence of protein synthesis, the polysomes from the rel⁺ strain are now converted mainly into subunits. It can be inferred, therefore, that ribosomes from rel^? bacteria, but not those from rel⁺ bacteria, continue movement over messenger RNA in the absence of protein synthesis.Studies of mixed extracts from rel^? and rel⁺ bacteria have shown that the character of the run-off process does not depend on the source of tRNA and soluble enzymes; the proportions of monosomes and subunits among the run-off products formed in the absence of protein synthesis depend only on the source of the polysomes. It is suggested that the mutation of the rel gene alters the functional architecture of ribosomes.