Translational regulation of the expression of ribosomal protein genes in Xenopus laevis

The mRNAs coding for ribosomal proteins (rp-mRNA) are subjected to translational control during Xenopus oogenesis and embryogenesis, and also during nutritional changes in Xenopus cultured cells. This regulation, which appears to respond to the cellular need for new ribosomes, operates by changing the fraction of rp-mRNA engaged on polysomes, each translated rp-mRNA molecule always remaining fully loaded with ribosomes. All rp-mRNAs analyzed up to now show this translational behavior, and also share some structural features in their untranslated portions. In particular they all have rather short 5' untranslated regions, similar to each other, and always start at the very 5' end with a stretch of several pyrimidines. Fusion to a reporter-coding sequence of the 5' untranslated region of r-protein S19 has shown that this is involved in the translational regulation.     

Free ribosomes and growth stimulation in human peripheral lymphocytes: Activation of free ribosomes as an essential event in growth induction

During the initial ten hours of growth in lymphocytes stimulated by phytohemagglutinin, the cells are converted from a state in which over 70% of all ribosomes are inactive free ribosomes, to one in which over 80% of ribosomes are in polysomes or in native ribosomal subunits. In this initial period, there was a neglible increase in total ribosomal RNA due to increased RNA synthesis, and abolition of ribosomal RNA synthesis with low concentrations of actinomycin D did not interfere with polysome formation. Therefore, the conversion is accomplished by the activation of existing free ribosomes rather than by accumulation of newly synthesized particles. The large free ribosome pool of resting lymphocytes is thus an essential source of components for accelerated protein synthesis early in lymphocyte activation, before increased synthesis can provide a sufficient number of new ribosomes. Free ribosomes accumulate once more after 24 to 48 hours of growth, when RNA and DNA synthetic activity are maximal. This reaccumulation of inactive ribosomes at the peak of growth activity may represent preparation for a return to the resting state where cells are again susceptible to stimulation. Activation of free ribosomes to form polysomes appears to involve modification of at least two steps: (a) dissociation of free ribosomes with stabilization as native subunits, and (b) adjustment of a rate-limiting step at initiation.     

Polysome formation and incorporation of new ribosomes into polysomes during germination of the embryonic axis of maize

Isolated axes of Zea mays L. cvs CiV₂ and CUZCO were imbibed for different periods of time, and free polysomes were extracted and analysed by centrifugation in a sucrose gradient. The amount of rRNA per axis was determined at different moments of germination. Polysome reassembly was practically completed by 8 h and 54% of the preformed ribosomes were found in the polysome fraction. An increase in the proportion of large polysomes was also observed during this period of germination. During the following period, the polysome content and the distribution of the various classes of polysomes remained unchanged.
The time of appearance of newly synthesized ribosomes into the polysomes was investigated using axes germinated in the presence of [³H]-uridine. Centrifugal analysis of EDTA-dissociated polysomes and gel electrophoretic analysis of polysomal RNA showed that new ribosomes appeared into polysomes a few hours after completion of the initial polysome assembly. When released into the cytoplasm, the new ribosomes were preferentially incorporated into polysomes rather than stored as free ribosomes.     

CONTROLLED PROTEOLYSIS OF NASCENT POLYPEPTIDES IN RAT LIVER CELL FRACTIONS : I. Location of the Polypeptides within Ribosomes

Free ribosomes containing nascent polypeptide chains labeled in vitro were submitted to proteolysis at 0° by a mixture of trypsin and chymotrypsin. Sucrose gradient analysis showed that polysome patterns are retained even after 24 hr of proteolysis in the cold, while messenger RNA-free ribosomes (generated progressively during in vitro incorporation) are, within 2 hr, completely dissociated into subunits by trypsin. Although ribosomes and subunits are not extensively degraded into smaller fragments during low temperature proteolysis, changes in the acrylamide gel electrophoresis pattern showed that most ribosomal proteins are accessible to and are partially degraded by the proteases. Ribosome-bound nascent polypeptides are partially resistant to proteolysis at 0°, although they are totally digested at 37° or when the ribosomal subunit structure is disrupted by other means. Radioactivity incorporated into nascent chains during incubation times shorter than 3 min was mostly resistant to digestion at 0°. A larger fraction of the initial radioactivity became degraded in ribosomes which incorporated for longer times. In these ribosomes, the amount of radioactivity which was resistant to proteolysis was constant and independent of the initial value, which reflects the labeled length of the nascent chains. These results suggest that the growing end of the nascent polypeptide is resistant to digestion and is protected from proteolytic attack by the ribosomal structure. A pulse and chase experiment confirmed this suggestion, showing that the protected segment is located at the carboxy-terminal end of the nascent chain. The protected segment was contained in the large ribosomal subunit and had a length of ~39 amino acid residues, as estimated by chromatography on Sephadex G-50.     

Characterization of hibernating ribosomes in mammalian cells

Protein synthesis across kingdoms involves the assembly of 70S (prokaryotes) or 80S (eukaryotes) ribosomes on the mRNAs to be translated. 70S ribosomes are protected from degradation in bacteria during stationary growth or stress conditions by forming dimers that migrate in polysome profiles as 100S complexes. Formation of ribosome dimers in Escherichia coli is mediated by proteins, namely the ribosome modulation factor (RMF), which is induced in the stationary phase of cell growth. It is reported here a similar ribosomal complex of 110S in eukaryotic cells, which forms during nutrient starvation. The dynamic nature of the 110S ribosomal complex (mammalian equivalent of the bacterial 100S) was supported by the rapid conversion into polysomes upon nutrient-refeeding via a mechanism sensitive to inhibitors of translation initiation. Several experiments were used to show that the 110S complex is a dimer of nontranslating ribosomes. Cryo-electron microscopy visualization of the 110S complex revealed that two 80S ribosomes are connected by a flexible, albeit localized, interaction. We conclude that, similarly to bacteria, rat cells contain stress-induced ribosomal dimers. The identification of ribosomal dimers in rat cells will bring new insights in our thinking of the ribosome structure and its function during the cellular response to stress conditions.     

Red-Far Red Reversible Effect on Polysome Formation in the Embryos of Pinus thunbergii Seeds

Polysome formation in the embryos of Pinus thunbergii seeds was studied. Free ribosomes were dissociated to smaller subunits in a high salt buffer, but the complex ribosomes were not. The free ribosomes could be distinguished from monomer ribosomes derived from polysomes after RNase treatment. The monomer ribosomes present in the embryos of the dark-imbibed seeds were predominantly free ribosomes; very small quantities of polysomes could be detected in the embryos from dark-imbibed seeds. Such polysomes remained at a very low level during dark imbibition at least for a month. The level of polysomes increased 4 hours after a brief exposure to red light. The effect of red light on polysome formation was partially reversed when followed by far red light irradiation.     

Rapidly labelled ribonucleic acid from rat liver. Studies in the attachment to ribosomes and stimulation of the incorporation of amino acids into polypeptides in cell-free systems

1. Rapidly labelled RNA from rat liver, either as a complex with DNA (m-RNA-DNA) or with ribosomal RNA (m-RNA-RNA) binds to ribosomes in the polysome region. No binding could be demonstrated with ribosomal RNA or native DNA from Bacillus subtilis. 2. With ribosomes from rat liver, Escherichia coli or hepatoma the m-RNA-DNA stimulated incorporation of amino acids with rat-liver ribosomes only, whereas the m-RNA-RNA complex was effective with ribosomes from E. coli or the hepatoma. 3. Polyuridylic acid was effective as messenger RNA with all three ribosomes but much greater stimulation was obtained with ribosomes from E. coli and the hepatoma. 4. The degree of incorporation of phenylalanine with polyuridylic acid and ribosomes from a hepatoma was decreased by about 50% when ribosomal RNA was present.     

Characterization of hibernating ribosomes in mammalian cells

Protein synthesis across kingdoms involves the assembly of 70S (prokaryotes) or 80S (eukaryotes) ribosomes on the mRNAs to be translated. 70S ribosomes are protected from degradation in bacteria during stationary growth or stress conditions by forming dimers that migrate in polysome profiles as 100S complexes. Formation of ribosome dimers in Escherichia coli is mediated by proteins, namely the ribosome modulation factor (RMF), which is induced in the stationary phase of cell growth. It is reported here a similar ribosomal complex of 110S in eukaryotic cells, which forms during nutrient starvation. The dynamic nature of the 110S ribosomal complex (mammalian equivalent of the bacterial 100S) was supported by the rapid conversion into polysomes upon nutrient-refeeding via a mechanism sensitive to inhibitors of translation initiation. Several experiments were used to show that the 110S complex is a dimer of nontranslating ribosomes. Cryo-electron microscopy visualization of the 110S complex revealed that two 80S ribosomes are connected by a flexible, albeit localized, interaction. We conclude that, similarly to bacteria, rat cells contain stress-induced ribosomal dimers. The identification of ribosomal dimers in rat cells will bring new insights in our thinking of the ribosome structure and its function during the cellular response to stress conditions.Key words: ribosome, translation, stress, starvation, polysome     

Effect of ozone on ribosomes in pinto bean leaves

A study was made of cytoplasmic and chloroplast ribosomes in the primary leaves of pinto bean plants exposed to ozone. The isolated ribosomes were analysed by sucrose density gradient. Ozone at the levels of 0·35 ppm for 20–35 min does not change the concentrations of various sedimenting particles of the cytoplasmic ribosomes. Ozone at similar levels, however, specifically decreases the population of chloroplast ribosomes per unit fresh weight of leaves. The distribution pattern of these chloroplast ribosomes is characterized by the low concentration of the fast-sedimenting polysome particles concomitant with the low magnitude of other slow-sedimenting components. The kinetics of ribosome populations during leaf growth demonstrates that ozone does not influence the daily levels of different ribosomal components of cytoplasmic ribosomes. However, ozone prematurely decreases the concentrations of polysomes and other components of chloroplast ribosomes below control level at the early stage of leaf development. These findings are discussed to explain initiation of the premature senescence caused by ozone.     

Ribosomes and Polysomes in Cucumber Leaves during Growth and Senescence

The quantity of RNA in the ribosomal fraction of the first leaf of cucumber (Cucumis sativus) increases during growth, reaches a maximum before the final fresh weight is attained, and then decreases. The main changes are in the free ribosome fraction, the quantity of membrane-bound ribosomes remaining about constant. Few 65.5S chloroplast ribosomes are present in small leaves; however, they increase in quantity rapidly during growth and form about half of the ribosomes present in the mature fully green leaf. The cytoplasmic ribosomes have a sedimentation coefficient of 77.6S. Ribonuclease-sensitive polysomes were present in leaves of all ages except possibly the very oldest. The proportion of ribosomes in polysome form decreases during growth and then remains roughly constant during senescence. Following maturation of the leaf, the rate of incorporation of ³²P into ribosomal-fraction RNA begins to decline. This decline could account for the loss of ribosomes during the early stages of senescence. The possibility that leaf ribonuclease might be responsible for the final, more rapid loss of RNA, is discussed.     

Changes in polyribosome populations during follicle cell maturation in the ovary of the bug, Oncopeltus fasciatus.

An examination of polyribosome profiles has revealed a distinction between the messenger RNA populations present during the delta, gamma-beta, and alpha₁ stages of the follicular epithelium. The delta and gamma-beta stages are both characterized by polysome profiles with no clearly prominent peaks. There is an increase both in the overall activity of the polysome region and in the amount of heavier polysomes in relation to the lighter ones during the transition from the delta to the gamma-beta condition. The alpha₁ oöcytes possess polysome profiles which are characterized by several extremely prominent peaks and by a reduction in the amount of single ribosomes in the cell. This is taken to indicate that the alpha₁ cells are engaged in the synthesis of large quantities of several different proteins, possibly the chorion precursors.     

Effects of phenobarbital on protein synthesis and polysome levels in rat liver.

Administration of phenobarbital to rats increases the rate of synthesis of certain microsomal drug-metabolizing enzymes in a selective manner and promotes proliferation of smooth endoplasmic reticulum in the liver. Phenobarbital increased a number of factors by which protein synthesis could be enhanced in the liver. It produced a 30% increase in the amount of ribosomes and mRNA per cell. The proportion of ribosomes associated with polysomes was increased by 5-10% over normal liver. There was a 10-30% increase in the rate of ploypeptide elongation and a small increase or no change in polysome size, indicating that the rate of polypeptide initiation was increased proportionately. The product of these effects accounts for the 1.5-fold increase in the rate of total protein synthesis previously reported. The average polysome size, and the size of free polysomes in particular, was maintained when actinomycin D was administered to phenobarbital-pretreated rats, suggesting that the rate of mRNA degradation was decreased selectively. Phenobarbital did not, however, affect the distribution of ribosomes between the free and membrane-bound states or the activity of ribonucleases associated with isolated free and bound polysomes. Thus, we conclude that phenobarbital stimulates protein synthesis by expanding the mRNA pool, at least partially through effects on mRNA degradation, and by augmenting the rate of mRNA translation.     

The relation of protein synthesis to the concentrations of free and membrane-bound ribosomes in brain at different ages

Free and membrane-bound ribosomes were prepared from the brains of young (3- and 8-day-old) and adult (30 day) rats by the method of Ramsey and Steele (1977). Though the concentration of RNA in young brain is higher than that in adult brain, the fraction of the RNA which is ribosomal is virtually the same (64%) as is the ratio of free ribosomes total ribosomes (61%) at all ages studied. The rate of protein synthesis measured in vivo, expressed in the usual terms of “% per h”, is much higher in young compared to adult brain, but when expressed as the ribosomal specific activity, i.e. “mg protein synthesized per hour per mg ribosomal RNA”, is the same in the three age groups (0.61, 0.58 and 0.60, respectively). Thus, even during early development, when protein is increasing rapidly, ribosomes are no more active than in adult brain, suggesting that synthesis rates in brain are limited by ribosomal content.     

The isolation and properties of cardiac ribosomes and polysomes

1. A method is described by which good yields of ribosomes and polysomes free of contamination by submitochondrial fragments can be prepared from rat cardiac muscle. These preparations are capable of incorporation of amino acids into protein in vitro. 2. The ribosome preparation consists of 32% of monomeric ribosomes and 68% of ribosomal aggregates or polysomes. The polysome preparation has a decreased monomeric content. Dimers, trimers, tetramers, pentamers and larger components can be differentiated. 3. The polysome aggregate structure is degraded to monomeric ribosomes on incubation with small amounts of ribonuclease or by preparation in the absence of Mg²⁺ ions. The degradation in the absence of Mg²⁺ ions was not reversible and drastically decreased the incorporation of amino acids in vitro. 4. The cardiac ribosomes contained two major RNA species sedimenting at 19s and 28s in a 1:2·4 ratio. 5. The RNA/protein ratio of cardiac ribosomes and polysomes was consistently lower than that of similar preparations from liver. The concentrations of Na⁺ and K⁺ ions present during preparation had a great effect on the RNA/protein ratio. 6. Optimum conditions for the incorporation of amino acids into protein in vitro are reported. Cardiac ribosomes have a lower rate of incorporation of amino acids in vitro than liver ribosomes. 7. Heart cell sap is less active than liver cell sap: evidence is presented that a factor, present in liver cell sap and concerned with stimulating the synthesis of the peptide chain, is lacking in heart cell sap. 8. Pulse-labelling of perfused hearts followed by examination of the subcellular structures showed that the ribosomal fraction was the most active in the incorporation of amino acids in vitro.     

Topography of 5.8 S rRNA in rat liver ribosomes. Identification of diethyl pyrocarbonate-reactive sites

The topography of 5.8 rRNA in rat liver ribosomes has been examined by comparing diethyl pyrocarbonate-reactive sites in free 5.8 S RNA, the 5.8 S-28 rRNA complex, 60 S subunits, and whole ribosomes. The ribosomal components were treated with diethyl pyrocarbonate under salt and temperature conditions which allow cell-free protein synthesis; the 5.8 S rRNA was extracted, labeled in vitro, chemically cleaved with aniline, and the fragments were analyzed by rapid gel-sequencing techniques. Differences in the cleavage patterns of free and 28 S or ribosome-associated 5.8 S rRNA suggest that conformational changes occur when this molecule is assembled into ribosomes. In whole ribosomes, the reactive sites were largely restricted to the "AU-rich" stem and an increased reactivity at some of the nucleotides suggested that a major change occurs in this region when the RNA interacts with ribosomal proteins. The reactivity was generally much less restricted in 60 S subunits but increased reactivity in some residues was also observed. The results further indicate that in rat ribosomes, the two -G-A-A-C- sequences, putative binding sites for tRNA, are accessible in 60 S subunits but not in whole ribosomes and suggest that part of the molecule may be located in the ribosomal interface. When compared to 5 S rRNA, the free 5.8 S RNA molecule appears to be generally more reactive with diethyl pyrocarbonate and the cleavage patterns suggest that the 5 S RNA molecule is completely restricted or buried in whole ribosomes.