Stimulation par l'Œstradiol de la synthèse des ribosomes dans les cellules adénohypophysaires

A single dose of 10 μg oestradiol injected to a male rat stimulates in the anterior pituitary the synthesis of ribosomal RNA and of the associated proteins. This stimulation is shown using in vitro double-labeling of RNA with adenine or guanine and of proteins with valine. The analysis of polysomes reveals the incorporation of the neo-synthesized molecules into the 40 S and 60 S subunits. Therefore, the stimulation of ribosomal RNA and protein biosynthesis by oestradiol is a coordinated process. No change in the whole polysome distribution is observed in these conditions though such a modification may occur in a specific cell population without being detected by using sucrose gradient analysis.     

Polyamine stimulation of ribosomal synthesis and activity in a polyamine-dependent mutant of Escherichia coli

A polyamine-dependent mutant of Escherichia coli KK101 was isolated by treatment of E. coli MA261 with N-methyl-N'-nitro-N-nitrosoguanidine. In the absence of putrescine, doubling time of the mutant was 496 min. The mutation was accompanied by a change in the nature of the 30 S ribosomal subunits. Addition of putrescine to the mutant stimulated the synthesis of proteins and subsequently, this led to stimulation of RNA and DNA synthesis. Under these conditions, we determined which proteins were preferentially synthesized. Putrescine stimulated the synthesis of ribosomal protein S1 markedly, but stimulated ribosomal proteins S4, L20, and X1, and RNA polymerase slightly. The amounts of initiation factors 2 and 3 synthesized were not influenced significantly by putrescine. The preferential stimulation of the synthesis of ribosomal protein S1 occurred as early as 20 min after the addition of putrescine, while stimulation of the synthesis of the other ribosomal proteins and RNA polymerase appeared at 40 min. The stimulation of the synthesis of ribosomal RNA also occurred at 40 min after addition of putrescine. Our results indicate that putrescine can stimulate both the synthesis and the activity of ribosomes. The increase in the activity of ribosomes was achieved by the association of S1 protein to S1-depleted ribosomes. The early stimulation of ribosomal protein S1 synthesis after addition of putrescine may be important for stimulation of cell growth by polyamines.     

Measurement of dendritic mRNA transport using ribosomal markers

mRNA is transported to the dendritic regions by forming RNA granules, an aggregate of mRNA, ribosomal proteins, rRNA, and RNA-binding proteins such as Staufen. In this study, the dendritic transport of RNA granules was measured using the individual antibodies to ribosome-specific markers such as ribosomal L4 or S6 protein, and Y10B, a monoclonal antibody specific to rRNA. All the markers showed significant immunoreactivity in the dendritic regions of the hippocampal neurons. In addition, a GFP-tagged Staufen, a marker protein of the RNA granules, was colocalized with the Y10B and S6 signals in the dendrites. The S6 signals were also colocalized with the Y10B signals in the dendrites. Consistent with previous studies, the depolarization induced by KCl stimulation increased the ribosomal level, revealed by the S6 or Y10B immunostaining in the distal dendrites. These results demonstrate the utility of ribosomal markers for detecting the RNA granules or mRNA transport in dendrites.     

Molecular interactions of ribosomal components

Summary The formation of a complex between individual 30S ribosomal proteins and 16S ribosomal RNA was studied by three techniques: zone centrifugation, molecular-sieve chromatography and electrophoresis in polyacrylamide gels. Five 30S proteins form a stable complex with the RNA under the conditions used to assemble ribosomes. Specific and nonspecific complex formation can be distinguished by an analysis of the concentration-dependence for complex formation. Similarly, competition experiments between heterologous proteins that bind to RNA can also be used to establish the uniquness of the RNA binding sites for ribosomal proteins. The data show that four of the five proteins bind to unique sites on the RNA. The fifth protein binds nonspecifically to the RNA. In addition, cooperative interactions between several proteins were observed; these enhance the interaction of proteins with the 16S RNA. A partial assembly sequence for the 30S ribosomal subunit is presented.     

Isolation of protein S6 from rat liver ribosomes by reversed-phase high-performance liquid chromatography

A rapid procedure for the isolation of ribosomal protein S6 from rat liver ribosomes has been developed in which proteins were separated by reversed-phase HPLC using wide-pore n-butyl-, n-octyl-, or diphenyl-bonded silica phases. Rapid processing of whole ribosomal material was achieved by the extraction of proteins in 6 M guanidinium hydrochloride and subsequent precipitation of RNA by acidification. Highly purified S6 was obtained in two chromatographic steps as shown by sodium dodecyl sulfate-gel electrophoresis, amino acid analysis, and automated microsequencing. The purification of S6 was monitored using 32P-labeled S6 as a marker which cochromatographed with unphosphorylated S6 under the low-pH elution conditions employed. Other ribosomal proteins were also purified using these reversed-phase supports, although in the case of more hydrophobic proteins such as S4 and S10 further optimization of the gradient conditions was required.     

Crosslinking of proteins to ribosomal RNA in HeLa cell polysomes by sodium periodate.

HeLa cell polysomes were oxidized with sodium periodate and reduced with sodium borohydride to induce covalent crosslinks between ribosomal RNA and nearby proteins. We proved that RNA was tryly crosslinked to protein in oxidized, and not in control, samples using denaturing cesium trichloroacetate density gradients and phenol extraction. By both one- and two-dimensional gel analysis, we found that protein S3a can be crosslinked to 18S RNA, protein L3 to 28S RNA, and proteins L7′ and L23′ to 5.8S RNA. Because of the specificity of the periodate reaction, and since we were able to crosslink protein S1 to 16S RNA in $\text{Escherichia}$,$\text{coli}$ 30S ribosomal subunits, it is likely that we have crosslinked proteins to the 3′OH ends of HeLa polysomal RNAs.     

Secondary structure of the 5'-terminal region of the 18S ribosomal RNA5.3S fragment from the rat liver

Two small RNA fragments, 5,3S and 4,7S, were observed in gel electrophoretic analysis of RNA of the 40S ribosomal subunit of rat liver. 5,3S RNA (134-136 nucleotides long) proved to be 5'-terminal fragment of 18S ribosomal RNA, whereas 4,7 RNA is the degradation product of 5,3S RNA with 27-28 5'-terminal nucleotides lost. The secondary structure of 5,3S RNA was probed with two structure-specific nucleases, S1 nuclease and the double-strand specific cobra venom endoribonuclease. The nuclease digestion data agree well with the computer generated secondary structure model for 5,3S RNA. This model predicts that the 5'-terminal part of rat liver ribosomal 18S RNA forms an independent structural domain. The affinity chromatography experiments with the immobilized 5,3S fragment show that 5,3S RNA does not bind rat liver ribosomal proteins.     

Molecular interactions of ribosomal components

Summary Five of the 30S ribosomal proteins from E. coli were tested for their ability to bind to 16S ribosomal RNA. Only one of these, S15, can form a complex with the RNA. Quantitative measurements as well as competition experiments show that the RNA binding site for the attachment of S15 is specific for this protein.These experiments complete our analysis of all 21 of the 30S ribosomal proteins. Five of these have now been shown to form a site-specific complex with 16S RNA. These are S4, S7, S8, S15 and S20. The relationship of these data to the assembly and structure of the ribosome are discussed.     

Mitochondrial and nuclear mutations that affect the biogenesis of the mitochondrial ribosomes of yeast. II. Biochemistry.

1. Several nuclear mutants have been isolated which showed thermo- or cryo-sensitive growth on non-fermentable media. Although the original strain carried mitochondrial drug resistance mutations (CR, ER, OR and PR), the resistance to one or several drugs was suppressed in these mutants. Two of them showed a much reduced amount of the mitochondrial small ribosomal subunit (37S) and of the corresponding 16S ribosomal RNA. Two dimensional electrophoretic analysis did not reveal any change in the position of any of the mitochondrial ribosomal proteins. However one of the mitochondrial ribosomal proteins. However one of the mutants showed a striking decrease in the amounts of three ribosomal proteins S3, S4 and S15. 2. Four temperature-sensitive mitochondrial mutations have been localized in the region of the gene coding for the large mitochondrial ribosomal RNA (23S). These mutants all showed a marked anomaly in the mitochondrial large ribosomal subunit (50S) and/or the corresponding 23S ribosomal RNA.     

Responsibility of 16S RNA for the stimulation of polypeptide synthesis by spermidine.

From the studies on the spermidine stimulation of polyphenylalanine synthesis catalyzed by $\text{E. coli}$ 50S and reconstituted 30S particles containing 16S RNA and 30S ribosomal proteins from $\text{E. coli}$ and $\text{B. thuringiensis}$ in different kinds of combinations, it is concluded that 16S RNA is mainly responsible for the stimulation of polypeptide synthesis by spermidine.     

RNA binding strategies of ribosomal proteins.

Structures of a number of ribosomal proteins have now been determined by crystallography and NMR, though the complete structure of a ribosomal protein-rRNA complex has yet to be solved. However, some ribosomal protein structures show strong similarity to well-known families of DNA or RNA binding proteins for which structures in complex with cognate nucleic acids are available. Comparison of the known nucleic acid binding mechanisms of these non-ribosomal proteins with the most highly conserved surfaces of similar ribosomal proteins suggests ways in which the ribosomal proteins may be binding RNA. Three binding motifs, found in four ribosomal proteins so far, are considered here: homeodomain-like alpha-helical proteins (L11), OB fold proteins (S1 and S17) and RNP consensus proteins (S6). These comparisons suggest that ribosomal proteins combine a small number of fundamental strategies to develop highly specific RNA recognition sites.     

Studies on the binding of the ribosomal protein complex L7/12-L10 and protein L11 to the 5''-one third of 23S RNA: a functional centre of the 50S subunit.

The RNA binding sites of the protein complex of L7/12 dimers and L10, and of protein L11, occur within the 5'-one third of 23S RNA. Binding of the L7/12-L10 protein complex to the 23S RNA is stimulated by protein L11 and vice-versa. This is the second example to be established of mutual stimulation of RNA binding by two ribosomal proteins or protein complexes, and suggests that this may be an important principle governing ribosomal protein-RNA assembly. When the L7/12-L10 complex is bound to the RNA, L10 becomes strongly resistant to trypsin. Since the L7/12 dimer does not bind specifically to the 23S RNA, this suggests that L10 constitutes a major RNA binding site of the protein complex. Only one of the L7/12 dimers is bound strongly in the (L7/12-L10)-23S RNA complex; the other can dissociate with no concurrent loss of L10.     

Crystal structure of the 30 S ribosomal subunit from Thermus thermophilus: structure of the proteins and their interactions with 16 S RNA

We present a detailed analysis of the protein structures in the 30 S ribosomal subunit from Thermus thermophilus, and their interactions with 16 S RNA based on a crystal structure at 3.05 A resolution. With 20 different polypeptide chains, the 30 S subunit adds significantly to our data base of RNA structure and protein-RNA interactions. In addition to globular domains, many of the proteins have long, extended regions, either in the termini or in internal loops, which make extensive contact to the RNA component and are involved in stabilizing RNA tertiary structure. Many ribosomal proteins share similar alpha+beta sandwich folds, but we show that the topology of this domain varies considerably, as do the ways in which the proteins interact with RNA. Analysis of the protein-RNA interactions in the context of ribosomal assembly shows that the primary binders are globular proteins that bind at RNA multihelix junctions, whereas proteins with long extensions assemble later. We attempt to correlate the structure with a large body of biochemical and genetic data on the 30 S subunit.     

Identification of several proteins involved in the messenger RNA binding site of the 30 S ribosome by inactivation with 2-methoxy-5-nitrotropone

Chemical modification of unwashed 30 S ribosomal subunits with 2-methoxy-5-nitrotropone causes a rapid loss of their capacity to bind bacteriophage Qβ RNA. Reconstitution experiments show that ribosomal protein is the functionally inactivated species. When purified unmodified ribosomal proteins were included in a mixture of 16 S ribosomal RNA and total protein derived from 2-methoxy-5-nitrotropone-treated subunits, four proteins (S1, S12, S13 and S21) were found to promote the reconstitution of particles capable of binding natural messenger RNA.     

Unbalanced rRNA gene dosage and its effects on rRNA and ribosomal-protein synthesis.

The synthesis of rRNA was unbalanced by the introduction of plasmids containing rRNA operons with large internal deletions. Significant unbalanced synthesis was achieved only when the deletions affected both 16S and 23S RNA genes or when the deletions affected the 23S RNA gene alone. Although large imbalances in rRNA synthesis resulted from deletions affecting 16S and 23S RNA genes or only 23S RNA genes, excess 16S RNA and defective rRNA species were rapidly degraded. Large imbalances in the synthesis of regions of rRNA did not result in significantly unbalanced synthesis of ribosomal proteins. It therefore is probable that excess intact 16S RNA is degraded because ribosomal proteins are not available for packaging the RNA into ribosomes. Defective RNA species also may be degraded for this reason or because proper ribosome assembly is prevented by the defects in RNA structure. We propose two possible explanations for the finding that unbalanced overproduction of binding sites for feedback ribosomal protein does not result in significant unbalanced translational feedback depression of ribosomal protein mRNAs.     

A method of preparing Escherichia coli 16 S RNA possessing previously unobserved 30 S ribosomal protein binding sites

A method of preparing 16 S RNA has been developed which yields RNA capable of binding specifically at least 12, and possibly 13, 30 S ribosomal proteins. This RNA, prepared by precipitation from 30 S subunits using a mixture of acetic acid and urea, is able to form stable complexes with proteins S3, S5, S9, S12, S13, S18 and possibly S11. In addition, this RNA has not been impaired in its capacity to interact with proteins S4, S7, S8, S15, S17 and S20, which are proteins that most other workers have shown to bind RNA prepared by the traditional phenol extraction procedure (Held et al., 1974; Garrett et al., 1971; Schaup et al., 1970,1971).We have applied several criteria of specificity to the binding of proteins to 16 S RNA prepared by the acetic acid-urea method. First, the new set of proteins interacts only with acetic acid-urea 16 S RNA and not with 16 S RNA prepared by the phenol method or with 23 S RNA prepared by the acetic acid-urea procedure. Second, 50 S ribosomal proteins do not interact with acetic acidurea 16 S RNA but do bind to 23 S RNA. Third, in the case of protein S9, we have shown that the bound protein co-sediments with acetic acid-urea 16 S RNA in a sucrose gradient. Additionally, a saturation binding experiment showed that approximately one mole of protein S9 binds acetic acid-urea 16 S RNA at saturation. Thus, we conclude that the method employed for the preparation of 16 S RNA greatly influences the ability of the RNA to form specific protein complexes. The significance of these results is discussed with regard to the in vitro assembly sequence.     

Cross-linking of Met-tRNAf to eIF-2 beta and to the ribosomal proteins S3a and S6 within the eukaryotic inhibition complex, eIF-2 .GMPPCP.Met-tRNAf.small ribosomal subunit.

In the quaternary initiation complex, eIF-2.GMPPCP.Met-tRNAf.40S ribosomal subunit, the Met-tRNAf can be cross-linked to the beta subunit of initiation factor eIF-2 as well as to ribosomal proteins S3a and S6 by treatment with the bifunctional reagent, diepoxybutane. Using 40S subunits, modified in advance with the heterobifunctional reagent, methyl-rho-azido-benzoylaminoacetimidate, Met-tRNAf is covalently bound to the same ribosomal proteins (S3a and S6) upon irradiation of the complex with ultraviolet light. Under both conditions proteins S3a and S6, together with a limited number of other ribosomal proteins, are covalently bound to 18S ribosomal RNA.     

Binding sites for ribosomal proteins S8 and S15 in the 16 S RNA of Escherichia coli.

A fragment of the 16 S ribosomal RNA of Escherichia coli that contains the binding sites for proteins S8 and S15 of the 30 S ribosomal subunit has been isolated and characterized. The RNA fragment, which sediments as 5 S, was partially protected from pancreatic RNAase digestion when S15 alone, or S8 and S15 together, were bound to the 16 S RNA. Purified 5 S RNA was shown to reassociate specifically with protein S15 by analysis of binding stoichiometry. Although interaction between the fragment and protein S8 alone could not be detected, the 5 S RNA selectively bound both S8 and S15 when incubated with an unfractionated mixture of 30-S subunit proteins. Nucleotide sequence analysis demonstrated that the 5 S RNA arises from the middle of the 16 S RNA molecule and encompasses approximately 150 residues from Sections C, C'1 and C'2. Section C consists of a long hairpin loop with an extensively hydrogen-bonded stem and is contiguous with Section C'1. Sections C'1 and C'2, although not contiguous, are highly complementary and it is likely that together they comprise the base-paired stem of an adjacent loop.