Determination of the time of polypeptide chain synthesis in animal experiments]

A method is worked out for the estimation of the time of polypeptide chain synthesis in animals in vivo. The time of the synthesis of "middle" polypeptide was found to be 1.45 min. in mouse liver cells under normal conditions, while in the presence of translation inhibitors, cycloheximide (20 mg/kg) and aurintricarboxilic acid (1 g/mg) the time of the synthesis increased in 2.7 and 2.5 times respectively. The time of polypeptide synthesis linearly increased with the increase of aurintricarboxilic acid dose.     

Kinetic characteristics of the translation of rat liver mitochondria incubated under various conditions

The mode of distribution of labelled amino acids between the nascent and completed polypeptides during incubation of rat liver mitochondria in vitro was studied. This distribution corresponds to protein synthesis of uneven type with a sharp deceleration (pause) during the translation of the middle part of mRNA. The correspondence manifests itself in the fact that i) regular increment of radioactivity of nascent and completed polypeptides in coupled mitochondria was observed in interval less then ts (time necessary for the synthesis of an average polypeptide), and, ii) serine hydroxamate or norleucine have much less effect on the labelling of total protein as well as on the duration of synthesis of an average polypeptide, as could be expected from their inhibition of unmasked elongation. The duration of an expected pause during translation might exceed 4-fold the time necessary for elongation of the largest part of the polypeptide.     

Kinetics of the in vivo synthesis of the polypeptide chain; the effect of translation inhibitors]

Effects of aurinetricarbonic acid and cycloheximide on kinetics of polypeptide chain synthesis and polyribosome protile in mouse liver cell in vivo are studied. Both compounds are found to decrease the absolute rate of protein synthesis and to increase the time of polypeptide synthesis. Cycloheximide changed the ratio of translating and non-translating ribosomes and different in size polyribosome types. Aurinetricarbonic acid exerts no effect on polyribosome profile. Effects of cycloheximide and aurinetricarbonic acid on kinetic parameters of translation and a mechanism of action of these compounds are studied.     

The interaction between newly-formed mRNA and ribosomal particles during retarded translation]

The formation of polyribosomes in mouse liver cells at the reduced-rate translation was studied by treatment with cycloheximide (CHI) and aurintricarboxylic (ATA) acid. An increase of polypeptide synthesis time by 1.7-2.7 times (0.5 mg CHI per 25 g of weight or 15 mg ATA per 25 g) leads to a delay of the entrance of newly formed cytoplasmic D-RNA into polyribosomes. These results are in agreement with the model of polyribosome formation from ribonucleoprotein precursors containing cytoplasmic D-RNA. On the other hand, in the presence of a CHI dose (5 mg/25 g) causing a dramatic (240-fold) increase of polypeptide synthesis time, the kinetics of entrance of newly formed D-RNA into polyribosomes does not differ from the normal one, and amount of the incorporated mRNA is even somewhat higher than under normal conditions. It is suggested that in this situation ribosomes are moving along the newly formed mRNA, and their movement is not accompanied by the synthesis of completed polypeptide chain.     

Partial characterizatio and proposed mode of action of inhibitory heLa cell surface polypeptides

Polypeptides removed from the HeLa cell surface by mild pronase treatment rapidly inhibit protein synthesis when added to HeLa cells or cell-free translation system derived from HeLa cells. The inhibitory activity is heat stable. Protein and carbohydrate components of these polypeptides are required for inhibition of protein synthesis in vivo and in vitro. Two peaks of activity can be recovered from polyacrylamide gels, corresponding to polypeptides with molecular weights of approximately 29 000 and 41 000. Inhibition of protein synthesis in cell-free translation systems appears to be primarily an effect on elongation of polypeptide chains, whereas in the intact cell the primary target may be polypeptide chain initiation.     

Mapping the genes of the vaccinia virus, coding membrane proteins p34 and p40, by mRNA hybridization selection]

The HindIII--J HindIII-F fragments of the vaccinia virus DNA strain Lister have been analysed by the technique of mRNA hybridization selection with the subsequent translation in cell-free protein synthesizing system from the rabbit reticulocytes. The viral mRNA hybridizable with the HindIII--J fragment was shown to direct the synthesis of 30 kDa polypeptide in the cell-free system. This polypeptide was demonstrated to react specifically with antiserum to plasma membrane protein p34. The viral mRNA hybridizable with the HindIII-F fragment was shown to direct the synthesis of 37 kDa polypeptide in the cell-free system. This polypeptide reacts specifically with antiserum to major membrane protein p40.     

Nitrate-induced changes in protein synthesis and translation of RNA in maize roots

Nitrate regulation of protein synthesis and RNA translation in maize (Zea mays L. var B73) roots was examined, using in vivo labeling with [³⁵S]methionine and in vitro translation. Nitrate enhanced the synthesis of a 31 kilodalton membrane polypeptide which was localized in a fraction enriched in tonoplast and/or endoplasmic reticulum membrane vesicles. The nitrate-enhanced synthesis was correlated with an acceleration of net nitrate uptake by seedlings during initial exposure to nitrate. Nitrate did not consistently enhance protein synthesis in other membrane fractions. Synthesis of up to four soluble polypeptides (21, 40, 90, and 168 kilodaltons) was also enhanced by nitrate. The most consistent enhancement was that of the 40 kilodalton polypeptide. No consistent nitrate-induced changes were noted in the organellar fraction (14,000g pellet of root homogenates). When roots were treated with nitrate, the amount of [³⁵S]methionine increased in six in vitro translation products (21, 24, 41, 56, 66, and 90 kilodaltons). Nitrate treatment did not enhance accumulation of label in translation products with a molecular weight of 31,000 (corresponding to the identified nitrate-inducible membrane polypeptide). Incubation of in vitro translation products with root membranes caused changes in the SDS-PAGE profiles in the vicinity of 31 kilodaltons. The results suggest that the nitrate-inducible, 31 kilodalton polypeptide from a fraction enriched in tonoplast and/or endoplasmic reticulum may be involved in regulating nitrate accumulation by maize roots.     

Effect of high salt treatment on influenza B viral protein synthesis in MDCK cells

Based on the information that high salt inhibits the initiation of cellular mRNA translation which depends on the function of the 5'-terminal structure of mRNA, we compared the effect of high salt on translation of host cellular mRNAs and influenza viral mRNAs, both of which are of 5'-terminal structure. Brief exposure of influenza B virus-infected MDCK cells to high salt medium resulted in a dose-dependent inhibition of viral polypeptide synthesis as well as of cellular polypeptide synthesis, but it had less effect on synthesis of viral polypeptides, particularly nonstructural protein (NS). Under these conditions the Na+ content of the infected cells was significantly increased. A similar salt effect on in vitro translation of viral and cellular mRNAs extracted from infected cells was also observed. There was no significant difference in sensitivity to hypertonic block of in vivo translation of influenza viral mRNAs and vesicular stomatitis virus mRNAs, the latter of which possess a virus-directed structure at the 5'-terminus.     

Coat protein synthesis during sporulation of Bacillus subtilis: immunological detection of soluble precursors to the 12,200-dalton spore coat protein.

Antibody specific to the 12,200-dalton spore coat protein of Bacillus subtilis was used to detect the synthesis of cross-reacting material during sporulation. Cross-reacting protein was first detected by immunoprecipitation after 4 h of development and represented at least 1 to 2% of the total soluble protein synthesis at 5.5 h. A polypeptide of 21,000 daltons was detected in immunoprecipitates by gel electrophoresis. This polypeptide did not accumulate in sporulating cells and was rapidly turned over at the time of coat deposition. In contrast, a 32,000-dalton polypeptide reacted with antibody when unlabeled cell protein was denatured with sodium dodecyl sulfate, separated by gel electrophoresis, and transferred to nitrocellulose paper. This polypeptide was not detected during cell growth or the first 3.5 h of development but was found to accumulate in sporulating cells at 5.5 h. The lack of detection of this polypeptide by immunoprecipitation of undenatured protein indicates that the antigenic sites which cross-reacted with antibody to the 12,200-dalton protein sequence were not exposed unless the molecular conformation was altered. The 32,000-dalton protein may be a primary translation product which is proteolytically processed into mature spore coat protein via a 21,000-dalton intermediate.     

Biosynthesis of intestinal microvillar proteins. Processing of aminopeptidase N by microsomal membranes.

The biosynthesis of small-intestinal aminopeptidase N (EC 3.4.11.2) was studied in a cell-free translation system derived from rabbit reticulocytes. When dog pancreatic microsomal fractions were present during translation, most of the aminopeptidase N synthesized was found in a membrane-bound rather than a soluble form, indicating that synthesis of the enzyme takes place on ribosomes attached to the rough endoplasmic reticulum. The microsomal fractions process the Mr-115 000 polypeptide, which is the primary translation product of aminopeptidase N, to a polypeptide of Mr 140 000. This was found to be sensitive to the action of endo-beta-N-acetylglucosaminidase H (EC 3.2.1.96), showing that aminopeptidase N undergoes transmembrane glycosylation during synthesis. The position of the signal sequence in aminopeptidase N was determined by a synchronized translation experiment. It was found that microsomal fractions should be added before about 25% of the polypeptide was synthesized to ensure processing to the high-mannose glycosylated form. This suggests that the signal sequence is situated in the N-terminal part of the aminopeptidase N. The size of the cell-free translation product in the absence of microsomal fractions was found to be similar to that on one of the forms of the enzyme obtained from tunicamycin-treated organ-cultured intestinal explants.     

Optimization of protein synthesis in isolated higher plant chloroplasts. Identification of paused translation intermediates

Protein synthesis in isolated, intact pea chloroplasts was optimized and compared to translation within chloroplasts in vivo. Many polypeptides labeled with [35S]methionine in isolated intact chloroplasts did not comigrate with polypeptides which were labeled within chloroplasts in vivo. Antibodies to the large subunit of ribulose-1,5-bisphosphate carboxylase-oxygenase (EC 4.1.1.39) immunoprecipitated [35S]-labeled large subunit plus several lower-molecular-mass translation products of isolated chloroplasts. The lower-molecular-mass soluble translation products synthesized in pulse-labeled chloroplasts were converted into full-length large-subunit polypeptides during a subsequent chase period. This result suggests that many of the polypeptides observed in pulse-labeled chloroplasts are incomplete translation products which are the result of ribosome pausing at discrete points along chloroplast mRNAs. The pulse-chase technique was used to follow synthesis of the 34.5-kDa precursor of the psb A gene product and its processing to the mature 32-kDa polypeptide in isolated chloroplasts. Chloroplast translation profiles obtained using the pulse-chase assay were very similar to translation profiles obtained in vivo thus extending the utility of protein synthesis in isolated chloroplasts.     

Identification and Properties of the Messenger RNA Activity in Chlamydomonas reinhardi Coding for the Large Subunit of d-ribulose-1,5-bisphosphate Carboxylase

Properties of the mRNA coding for the large subunit of ribulose-1,5-bisphosphate carboxylase from Chlamydomonas reinhardi were determined. Large subunit synthesis, directed by RNA from partially purified whole cell extracts, was detected by specific immunoprecipitation of polypeptide products synthesized in a heterologous translation system derived from Escherichia coli. Large subunit synthesis showed sharp RNA concentration dependence in an E. coli translation system, and at optimal RNA concentrations, immunoprecipitable large subunit synthesis accounted for 2% of the total incorporation. Large subunit messenger activity sedimented at 12 to 14S on nondenaturing sucrose gradients and did not bind to oligo(dT)-cellulose suggesting the mRNA is not polyadenylated. The immunoprecipitable products translated in vitro are not complete polypeptide chains, but are smaller peptides identifiable as large subunit fragments by tryptic fingerprint analysis. No immunoprecipitable product was obtained when similar RNA fractions were tested in a wheat germ translation system.     

Heat-shock protein synthesis in Chlamydomonas reinhardi. Translational control at the level of initiation of a poly(A)-rich-RNA coded 22-KDa protein in a cell-free system

The effect of temperature on the in vitro translation of control and heat-shock poly(A)-rich RNA, obtained from Chlamydomonas reinhardi cells, incubated for 2 h at 25 degrees C respectively, was studied using the wheat-germ translation system. Incubation of the cells at 42 degrees C induces the synthesis of RNAs coding for several heat-shock proteins, including a 22-kDa major polypeptide as well as several proteins of 45-94 kDa, as demonstrated by run-off translation of polyribosomes isolated from intact cells. However, the high-molecular-mass heat-shock proteins are poorly translated in the wheat-germ system. The poly(A)-rich RNA coding for the 22-kDa heat-induced polypeptide has an apparent sedimentation coefficient higher than that expected from the molecular mass of its translation product, and was preferentially translated in vitro at temperatures above 31 degrees C as compared with pre-existing RNAs. Raising the temperature of translation, slightly inhibited (10%) the runoff translation of polyribosomes isolated from intact cells. However, when initiation was carried out in vitro for a short time at increasing temperatures and translation continued at 25 degrees C in the presence of aurintricarboxylic acid, the 22-kDa heat-shock polypeptides was preferentially translated. Aurintricarboxylic acid did not significantly inhibit incorporation of [35S]methionine when added to polyribosomes isolated from control or heat-shocked cells. From the above data we conclude that the translation of the 22-kDa heat-shock protein is controlled in vitro at the initiation level.     

Comparison of the expression of the src gene of Rous sarcoma virus in vitro and in vivo.

We have compared the polypeptide products of the src gene of several strains of Rous sarcoma virus produced by in vitro translation of heat-denatured 70S virion RNA in the nuclease-treated reticulocyte lysate with those present in chick cells transformed by these viruses. We have done this by immunoprecipitation, using sera from rabbits injected at birth with Schmidt-Ruppin Rous sarcoma virus. In vitro translation results in the synthesis of at least nine polypeptides which appear to be encoded by the src gene. These range in size from 17,000 to 60,000 daltons. The sera from tumor-bearing rabbits precipitated these polypeptides arising from the in vitro translation of RNA from Schmidt-Ruppin Rous sarcoma virus of both subgroup A and subgroup D and from one stock of Prague Rous sarcoma virus of subgroup C. In each case, all of this family of related polypeptides could be precipitated except the smallest, the 17,000-dalton polypeptide. No precipitation of analogous polypeptides resulting from the translation of RNA from other strains of Rous sarcoma virus was observed. Cells transformed by these three strains of Rous sarcoma virus contain easily detectable amounts of a polypeptide, p60src, essentially identical to the 60,000-dalton in vitro product. With one exception, they do not contain significant amounts of polypeptides analogous to the smaller in vitro products which can be precipitated by these sera. Cells transformed by one stock of Schmidt-Ruppin Rous sarcoma virus of subgroup A did contain a 39,000-dalton polypeptide, which was related, by peptide mapping, to the 60,000-dalton polypeptide and was similar in size to a precipitable in vitro product. The 60,000-dalton polypeptide present in transformed cells appeared to be phosphorylated 10 to 25 min after its synthesis, metabolically very stable, and not derived from a precursor polypeptide. All immunoprecipitates from transformed cells which contained p60src also contained an 80,000-dalton phosphoprotein. This polypeptide is unrelated to p60src, as determined by peptide mapping, and may well be a host cell polypeptide which is specifically associated with p60src.     

Preproceruloplasmin is a primary product of cell-free translation of ceruloplasmin messenger RNA

Summary Biosynthesis of ceruloplasmin was studied in wheat germ extract programmed with polysomal RNA from rat liver. Optimal potassium concentration for the total protein-synthesizing activity and for the synthesis of immunoreactive ceruloplasmin was 96 and 186 mM respectively. 7-methylguanosine 5′-monophosphate caused two-fold inhibition of the cell-free synthesis of ceruloplasmin. Immunoprecipitated ceruloplasmin that was synthesized at optimal potassium concentration was a homogeneous polypeptide of a molecular weight about 84 kD. The addition of membrane fractions from rat liver to the incubation mixture caused the conversion of the 84 kD polypeptide into 80 kD and 65 kD polypeptides that are similar to proceruloplasmins synthesized in rat liver during in vivo pulse labelling. The suggestion is made that 84 kD polypeptide is a primary product of the translation of ceruloplasmin mRNA (preproceruloplasmin).     

The study of spermidine-stimulated polypeptide synthesis in cell-free translation of mRNA from lactating mouse mammary gland

The stimulatory effect of spermidine on the translation of poly(A)⁺ mRNA from lactating mouse mammary glands in a wheat germ system was studied. Spermidine stimulated total polypeptide synthesis about 2.5-fold relative to that occurring in the presence of an optimal concentration of Mg²⁺ alone. The size and the number of polysomes were about 1.6-times larger in the presence of spermidine than in its absence. A similar magnitude of increase in peptide chain initiation, 1.4-fold, was found when the extent of peptide chain initiation was measured by determining the residual polypeptide synthesis subsequent to the addition of inhibitor(s) of peptide chain initiation to the in vitro translation system with or without spermidine at various times of the incubation. Time-course study of the release of polypeptide from polysomes showed that spermidine stimulated this process to a much greater extent than peptide chain initiation, indicating that the polyamine also increases the rate of peptide chain elongation. The extent of stimulation of peptide chain elongation by spermidine was estimated to be about 1.5-fold when the disappearance of isotope-labeled nascent peptides from polysomes was measured by pulse-chase experiments. These results indicate that spermidine stimulates the cell-free translation of mammary mRNA by increasing the rates of both initiation and elongation of polypeptide synthesis to almost the same extent. The polyamine also reduced the relative amount of incomplete polypeptides, thereby increasing the yield of full-length translational products.