The PRC-barrel domain of the ribosome maturation protein RimM mediates binding to ribosomal protein S19 in the 30S ribosomal subunits

The RimM protein in Escherichia coli is associated with free 30S ribosomal subunits but not with 70S ribosomes. A DeltarimM mutant is defective in 30S maturation and accumulates 17S rRNA. To study the interaction of RimM with the 30S and its involvement in 30S maturation, RimM amino acid substitution mutants were constructed. A mutant RimM (RimM-YY-->AA), containing alanine substitutions for two adjacent tyrosines within the PRC beta-barrel domain, showed a reduced binding to 30S and an accumulation of 17S rRNA compared to wild-type RimM. The (RimM-YY-->AA) and DeltarimM mutants had significantly lower amounts of polysomes and also reduced levels of 30S relative to 50S compared to a wild-type strain. A mutation in rpsS, which encodes r-protein S19, suppressed the polysome- and 16S rRNA processing deficiencies of the RimM-YY-->AA but not that of the DeltarimM mutant. A mutation in rpsM, which encodes r-protein S13, suppressed the polysome deficiency of both rimM mutants. Suppressor mutations, found in either helices 31 or 33b of 16S rRNA, improved growth of both the RimM-YY-->AA and DeltarimM mutants. However, they suppressed the 16S rRNA processing deficiency of the RimM-YY-->AA mutant more efficiently than that of the DeltarimM mutant. Helices 31 and 33b are known to interact with S13 and S19, respectively, and S13 is known to interact with S19. A GST-RimM but not a GST-RimM(YY-->AA) protein bound strongly to S19 in 30S. Thus, RimM likely facilitates maturation of the region of the head of 30S that contains S13 and S19 as well as helices 31 and 33b.     

On the interaction of ribosomal protein L5 with 5S rRNA

Ribosomal protein L5, a 5S rRNA binding protein in the large subunit, is composed of a five-stranded antiparallel beta-sheet and four alpha-helices, and folds in a way that is topologically similar to the ribonucleprotein (RNP) domain [Nakashima et al., RNA 7, 692-701, 20011. The crystal structure of ribosomal protein L5 (BstL5) from Bacillus stearothermophilus suggests that a concave surface formed by an anti-parallel beta-sheet and long loop structures are strongly involved in 5S rRNA binding. To identify amino acid residues responsible for 5S rRNA binding, we made use of Ala-scanning mutagenesis of evolutionarily conserved amino acids occurred at beta-strands and loop structures in BstL5. The mutation of Lys33 at the beta 1-strand caused a significant reduction in 5S rRNA binding. In addition, the Arg92, Phe122, and Glu134 mutations on the beta2-strand, the alpha3-beta4 loop, and the beta4-beta5 loop, respectively, resulted in a moderate decrease in the 5S rRNA binding affinity. In contrast, mutation of the conserved residue Pro65 at the beta2-strand had little effect on the 5S rRNA binding activity. These results, taken together with previous results, identified Lys33, Asn37, Gln63, and Thr90 on the beta-sheet structure, and Phe77 at the beta2-beta3 loop as critical residues for the 5S rRNA binding. The contribution of these amino acids to 5S rRNA binding was further quantitatively evaluated by surface plasmon resonance (SPR) analysis by the use of BIAcore. The results showed that the amino acids on the beta-sheet structure are required to decrease the dissociation rate constant for the BstL5-5S rRNA complex, while those on the loops are to increase the association rate constant for the BstL5-5S rRNA interaction.     

On the role of protein S4 N-terminal residues 1 through 30 in 30S ribosome function.

30S ribosomal protein S4 contains a single cysteine residue at position 31. We have selectively cleaved the peptide bond adjacent to this residue using the reagent 2-nitro-5-thiocyanobenzoic acid. The two resultant fragments were purified. The smaller S4-fragment (1-30) was found to be incapable of interacting with 16S RNA directly. This fragment also is not incorporated into a particle reconstituted from 16S RNA and 20 purified proteins with S4 missing. In contrast, the large S4-fragment (31-203) appears to be fully functional in ribosome assembly. Replacement of S4 with this fragment in the reconstitution reaction leads to a complete 30S ribosome containing all 30S proteins. This particle has a full capacity to bind poly U but has lost all activity for poly U directed phe-tRNA binding. We therefore propose that the N-terminus of protein S4 is not critical for ribosome assembly but is essential for tRNA binding.     

The mechanism of action of initiation factor 3 in protein synthesis. II. Association of the 30S ribosomal protein S12 with IF-3

Dimethylsuberimidate was used to crosslink ¹⁴C-labeled chain initiation factor 3 to $\text{E. coli}$ 30S particles. The crosslinked ribosomal proteins were analyzed by dodecyl sulfate polyacrylamide gel electrophoresis, and one major radioactive aggregate was found corresponding to a molecular weight of 41,000. Ribosomal protein S12 was identified to be crosslinked to IF-3 by immunological cross-reactivity.     

rRNA topography in ribosome. IV. The accessibility of the 5'-end region of 16S rRNA

The accessibility of the 5'-end region of 16S rRNA (A₈GAGUUUG₁₅) inEscherichia coli ribosomes for complementary binding with the synthetic octanucleotide d(CAAACTCT) has been studied. Nonequilibrium gel-filtration was used to evaluate parameters of the binding of this oligonucleotide with free 16S rRNA, ribosomal subunits, and 70S ribosomes. A simple approach is presented to calculate the apparent association constants and the number of binding sites based upon the data obtained under those conditions. Free 16S rRNA, 30S subunits, and 70S ribosomes were found to form rather stable complexes with the octanucleotide, the association constants being similar in all three cases. These data strongly suggest the surface location of the 16S rRNA 5'-end inE. coli ribosomes.     

The accessibility of antigenic determinants of ribosomal protein s4 in situ

Antibodies to Escherichia coli ribosomal protein S4 react with S4 in subribosomal particles, eg, the complex of 16S RNA with S4, S7, S8, S15, S16, S17, and S19 and the RI* reconstitution intermediate, but they do not react with intact 30S subunits. Antibodies were isolated by three different methods from antisera obtained during the immunization of eight rabbits. Some of these antibody preparations, which contained contaminant antibodies directed against other ribosomal proteins, reacted with subunits, but this reaction was not affected by removal of the anti-S4 antibody population. Other antibody preparations did not react with subunits. It is concluded that the antigenic determinants of S4 are accessible in some protein deficient subribosomal particles but not in intact 30S subunits.     

The structure of the archaebacterial ribosomal protein S7 and its possible interaction with 16S rRNA.

Ribosomal protein S7 is one of the ubiquitous components of the small subunit of the ribosome. It is a 16S rRNA-binding protein positioned close to the exit of the tRNA, and it plays a role in initiating assembly of the head of the 30S subunit. Previous structural analyses of eubacterial S7 have shown that it has a stable alpha-helix core and a flexible beta-arm. Unlike these eubacterial proteins, archaebacterial or eukaryotic S7 has an N-terminal extension of approximately 60 residues. The crystal structure of S7 from archaebacterium Pyrococcus horikoshii (PhoS7) has been determined at 2.1 A resolution. The final model of PhoS7 consists of six major alpha-helices, a short 3(10)-helix and two beta-stands. The major part (residues 18-45) of the N-terminal extension of PhoS7 reinforces the alpha-helical core by well-extended hydrophobic interactions, while the other part (residues 46-63) is not visible in the crystal and is possibly fixed only by interacting with 16S rRNA. These differences in the N-terminal extension as well as in the insertion (between alpha1 and alpha2) of the archaebacterial S7 structure from eubacterial S7 are such that they do not necessitate a major change in the structure of the currently available eubacterial 16S rRNA. Some of the inserted chains might pass through gaps formed by helices of the 16S rRNA.     

Functional interaction of neomycin B and related antibiotics with 30S and 50S ribosomal subunits.

Antibiotics of the neomycin, kanamycin and gentamicin, but not streptomycin, groups stabilize the GDP·elongation factor (EF) G·50S subunit·fusidic acid complex. Treatment of 30S subunits, but not of 50S subunits, with neomycin B or kanamycin B, followed by removal of excess unbound antibiotic and supplementation with untreated complementary subunits, promotes poly(U)-dependent binding of Tyr-tRNA to the reassociated ribosomes (misreading). A similar treatment of either ribosomal subunit with neomycin B inhibits the EF-G-dependent translocation of Ac-Phe-tRNA. These results suggest that interaction of neomycin B and related antibiotics with the 30S subunit induces misreading and inhibits translocation, and interaction with the 50S subunit stabilizes EF-G on the ribosome and also inhibits translocation.     

A functional interaction between ribosomal proteins S7 and S11 within the bacterial ribosome

In this study, we used site-directed mutagenesis to disrupt an interaction that had been detected between ribosomal proteins S7 and S11 in the crystal structure of the bacterial 30 S subunit. This interaction, which is located in the E site, connects the head of the 30 S subunit to the platform and is involved in the formation of the exit channel through which passes the 30 S-bound messenger RNA. Neither mutations in S7 nor mutations in S11 prevented the incorporation of the proteins into the 30 S subunits but they perturbed the function of the ribosome. In vivo assays showed that ribosomes with either mutated S7 or S11 were altered in the control of translational fidelity, having an increased capacity for frameshifting, readthrough of a nonsense codon and codon misreading. Toeprinting and filter-binding assays showed that 30 S subunits with either mutated S7 or S11 have an enhanced capacity to bind mRNA. The effects of the S7 and S11 mutations can be related to an increased flexibility of the head of the 30 S, to an opening of the mRNA exit channel and to a perturbation of the proposed allosteric coupling between the A and E sites. Altogether, our results demonstrate that S7 and S11 interact in a functional manner and support the notion that protein-protein interactions contribute to the dynamics of the ribosome.     

Arginine methylation of ribosomal protein S3 affects ribosome assembly

The human ribosomal protein S3 (rpS3), a component of the 40S small subunit in the ribosome, is a known multi-functional protein with roles in DNA repair and apoptosis. We recently found that the arginine residue(s) of rpS3 are methylated by protein arginine methyltransferase 1 (PRMT1). In this paper, we confirmed the arginine methylation of rpS3 protein both in vitro and in vivo. The sites of arginine methylation are located at amino acids 64, 65 and 67. However, mutant rpS3 (3RA), which cannot be methylated at these sites, cannot be transported into the nucleolus and subsequently incorporated into the ribosome. Our results clearly show that arginine methylation of rpS3 plays a critical role in its import into the nucleolus, as well as in small subunit assembly of the ribosome.     

Mechanism of the interaction between ribosomal protein S1 and oligonucleotides.

The interaction of the ribosomal protein S1 from E. coli MRE 600 with oligonucleotides was studied by hydrodynamic, spectrophotometric, and kinetic methods. UV-difference spectra which are induced by the complex formation could be separated into a hyperchromic contribution originating from the nucleic acid moiety and a hypochromic contribution from the protein. Systematic determination of binding and rate constants was carried out by the temperature-jump relaxation technique. From the quantitative evaluation of the relaxation times and the relaxation amplitudes, the following conclusions could be drawn: The stoichiometry of the complex formation is one mole S1 per one mole oligonucleotide. The binding constant K, the recombination rate constant kR, and the dissociation rate constant kD, respectively, were measured at different temperatures. The values at 10 degrees C are K = 2 x 10(6) M-1, kR = 1.3 x 10(8) M-1S-1, kD = 65 s-1 for A(pA) 12 and K = 7.5 x 10(5) M-1, kR = 6.8 x 10(7) M-1S-1, kD = 90 S-1 for U(pU) 12. Discrepancies with data reported elsewhere are discussed. The stacking-unstacking equilibrium of the free oligonucleotide is frozen if the oligonucleotide is bound to the protein. The conformational change of the oligonucleotide does not occur in the form of a preequilibrium, but is induced after the primary binding step.     

Cross-linking between 16S ribosomal RNA and protein S4 in Escherichia coli ribosomal 30S subunits effected by treatment with bisulfite/hydrazine and bromopyruvate

Cytosine in nucleic acids can be modified by treatment with a mixture of bisulfite and hydrazine. The reaction is specific for single-stranded regions of nucleic acids and the product is N4-aminocytosine. Bromopyruvate has been used for alkylation of protein SH groups and through its 2-oxo group it can form a hydrazone with N4-aminocytosine. Escherichia coli ribosomal 30S subunits were treated with 1 M sodium bisulfite + 2 M hydrazine in the presence of 10 mM MgCl2 at pH 7.0 and 37 degrees C for 30 min. By this treatment, 2.4 cytosine residues/molecule 16S rRNA were derivatized into N4-aminocytosines. 35S-labeled 30S subunits were modified in this way and then treated with 10 mM bromopyruvate at pH 8.0 and 37 degrees C for 5 min. Analysis in sodium dodecyl sulfate/sucrose density gradient centrifugation showed co-sedimentation of a part of the 35S radioactivity with the RNA. The co-sedimentation was dependent on both the bisulfite/hydrazine and the bromopyruvate treatments. The RNA-protein complex was prepared from unlabeled 30S subunits. The protein portion was labeled with 125I, the RNA portion was digested with nucleases, and then the hydrazone linkage between the protein and oligonucleotides was cleaved by treatment with 0.2 M HCl. The oligonucleotides formed were removed by dialysis and the protein was identified as S4 by two-dimensional electrophoresis and by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The results indicate that the cysteinyl residue of protein S4 at position 31 from the N-terminus is located close to a cytosine residue which is non-base-paired and easily accessible by the externally present bisulfite/hydrazine reagent.