Ribosomal proteins S3, S6, S8 and S10 of Escherichia coli localized on the external surface of the small subunit by immune electron microscopy

The ribosome comes to life

The ribosome, together with its tRNA substrates, links genotype to phenotype by translating the genetic information carried by mRNA into protein. During the past half-century, the structure and mechanisms of action of the ribosome have emerged from mystery and confusion. It is now evident that the ribosome is an ancient RNA-based molecular machine of staggering structural complexity and that it is fundamentally similar in all living organisms. The three central functions of protein synthesis-decoding, catalysis of peptide bond formation, and translocation of mRNA and tRNA-are based on elegant mechanisms that evolved from the properties of RNA, the founding macromolecule of life. Moreover, all three of these functions (and even life itself) seem to proceed in defiance of entropy. Protein synthesis thus appears to exploit both the energy of GTP hydrolysis and peptide bond formation to constrain the directionality and accuracy of events taking place on the ribosome.

Nucleotides in 16S rRNA protected by the association of 30S and 50S ribosomal subunits

We have studied the interaction of 16S rRNA in 30S subunits with 50S subunits using a series of chemical probes that monitor the accessibility of the RNA bases and backbone. The probes include 1-cyclohexyl-3-(2-morpholinoethyl) carbodiimide metho-p-toluene sulfonate (CMCT; to probe U at N-3 and G at N-1), diethylpyrocarbonate (DEPC; to probe A at N-7), dimethyl sulfate (DMS; to probe A at N-1, and C at N-3), kethoxal (to probe G at N-1 and N-2), hydroxyl radicals generated by free Fe(II)-EDTA (to probe the backbone ribose groups) and Pb(II). The sites of reaction were identified by primer extension of the probed RNA. Association of the subunits protects the bases of 11 nucleotides and the ribose groups of over 90 nucleotides of 16S rRNA. The nucleotides protected from the base-specific probes are often adjacent to one another and surrounded by sugar-phosphate backbone protections; thus, the results obtained with the different probes confirmed each other. Most of the protected nucleotides occur in five extended-stem-loop structures around positions 250, 700, 790, 900, and 1408-1495. These regions are located in the platform and bottom of the subunit in the general vicinity of inter-subunit bridges that are visible in reconstructed electron micrographs. Our results provide an extensive map of the nucleotides in 16S rRNA that are likely to be involved in subunit-subunit interactions.

Proteins on ribosome surface: measurements of protein exposure by hot tritium bombardment technique

The hot tritium bombardment technique [Goldanskii, V. I., Kashirin, I. A., Shishkov, A. V., Baratova, L. A. & Grebenshchikov, N. I. (1988) J. Mol. Biol. 201,567-574] has been applied to measure the exposure of proteins on the ribosomal surface. The technique is based on replacement of hydrogen by high energy tritium atoms in thin surface layer of macromolecules. Quantitation of tritium radioactivity of each protein has revealed that proteins S1, S4, S5, S7, S18, S20, and S21 of the small subunit, and proteins L7/L12, L9, L10, L11, L16, L17, L24, and L27 of the large subunit are well exposed on the surface of the Escherichia coli 70 S ribosome. Proteins S8, S10, S12, S16, S17, L14, L20, L29, L30, L31, L32, L33, and L34 have virtually no groups exposed on the ribosomal surface. The remaining proteins are found to be exposed to lesser degree than the well exposed ones. No additional ribosomal proteins was exposed upon dissociation of ribosomes into subunits, thus indicating the absence of proteins on intersubunit contacting surfaces.

Crystal structure of the ribosomal protein S6 from Thermus thermophilus

The amino acid sequence and crystal structure of the ribosomal protein S6 from the small ribosomal subunit of Thermus thermophilus have been determined. S6 is a small protein with 101 amino acid residues. The 3D structure, which was determined to 2.0 A resolution, consists of a four-stranded anti-parallel beta-sheet with two alpha-helices packed on one side. Similar folding patterns have been observed for other ribosomal proteins and may suggest an original RNA-interacting motif. Related topologies are also found in several other nucleic acid-interacting proteins and based on the assumption that the structure of the ribosome was established early in the molecular evolution, the possibility that an ancestral RNA-interacting motif in ribosomal proteins is the evolutionary origin for the nucleic acid-interacting domain in large classes of ribonucleic acid binding proteins should be considered.

Immunoelectron microscopic localization of ribosomal proteins BS8, BS9, BS20, BL3 and BL21 on the surface of 30S and 50S subunits from Bacillus stearothermophilus

The locations of ribosomal proteins BS8, BS9 and BS20 on the 30S subunit of Bacillus stearothermophilus ribosomes, and of BL3 and BL21 on the 50S subunit, were determined by immunoelectron microscopy. BL3 was found to lie half-way down the body of the 50S subunit on the interface side, below the L7/L12 stalk, in agreement with the placement of the corresponding protein in Escherichia coli by neutron-scattering; BL21 was located at a similar position on the solvent side of the subunit, as predicted by cross-linking experiments with E. coli ribosomes. Similarly, BS8 was found in the upper region of the body of the 30S subunit on the solvent side, and BS9 on the top of the head of the subunit, also on the solvent side, both positions being in good agreement with neutron-scattering data and other immunoelectron microscopy results. In contrast, BS20 was found to lie at the extreme base of the body of the 30S subunit; this placement is not compatible with the location of E. coli S20 by neutron-scattering but fits very plausibly with other biochemical data, such as sites of RNA-protein footprinting on 16S RNA, relating to the location of S20 in E. coli.

Epitope mapping of monoclonal antibodies to Escherichia coli ribosomal protein S3

The antigenic structure of Escherichia coli ribosomal protein S3 has been investigated by use of monoclonal antibodies. Six S3-specific monoclonal antibodies secreted by mouse hybridomas have been identified by immunoblotting of two-dimensional ribosomal protein separation gels. By using a competitive enzyme-linked immunosorbent assay, we have divided these monoclonal antibodies into three mutual inhibition groups, members of which are directed to three distinct regions of the S3 molecule. The independence of these monoclonal antibody-defined regions was confirmed by the failure of pairs of monoclonal antibodies from two inhibition groups to block the binding of biotinylated monoclonal antibodies of the third group. To determine the regions recognized by these monoclonal antibodies, chemically cleaved S3 peptides were fractionated by gel filtration and reverse-phase high-performance liquid chromatography. The fractionated peptides were coated on plates and examined for specific interaction with monoclonal antibody by enzyme immunoassay. In this manner, two epitopes have been mapped at the ends of the S3 molecule: one, in the last 22 residues, is recognized by three monoclonal antibodies; and the second, in the first 21 residues, is defined by two monoclonal antibodies. The third S3 epitope, recognized by a single monoclonal antibody, has been localized in a central segment of about 90 residues by gel electrophoresis and immunoblotting. These epitope-mapped monoclonal antibodies are valuable probes for studying S3 structure in situ.

DNA-hybridization electron microscopy tertiary structure of 16 S rRNA

Seven regions of 16 S rRNA have been located on the surface of the 30 S ribosomal subunit by DNA-hybridization electron microscopy. This information has been incorporated into a model for the tertiary structure of 16 S rRNA, accounting for approximately 40% of the total 16 S rRNA. A structure labeled the platform ring is proposed for a region of rRNA within the central domain. This structure rings the edges of the platform and includes regions 655-751 and 769-810. Another region, the recognition complex, consists of nucleotides 500 to 545, and occupies a region on the exterior surface of the subunit near the elongation factor Tu binding site. Ribosomal proteins that have been mapped by immunoelectron microscopy are superimposed onto the model in order to examine possible regions of interaction. Good correlation between the model locations of ribosomal proteins, and regions of rRNA protected by ribosomal proteins provide independent support for this model.

The topography of ribosomal proteins on the surface of the 30S subunit of Escherichia coli

Eight ribosomal proteins, S6, S10, S11, S15, S16, S18, S19 and S21 have been localized on the surface of the 30S subunit from Escherichia coli by immuno electron microscopy. The specificity of the antibody binding sites was demonstrated by stringent absorption experiments. In addition we have reinvestigated and refined the locations of proteins S5, S13 and S14 on the ribosomal surface which had previously been localized in our laboratory (Tischendorf et al., Mol. Gen. Genet. 134, 209-223, 1974). Thus altogether 16 out of the 21 ribosomal proteins of the small subunit from E. coli have been mapped in our laboratory.

Distribution of protein and RNA in the 30S ribosomal subunit

In Escherichia coli, the small ribosomal subunit has a sedimentation coefficient of 30S, and consists of a 16S RNA molecule of 1541 nucleotides complexed with 21 proteins. Over the last few years, a controversy has emerged regarding the spatial distribution of RNA and protein in the 30S subunit. Contrast variation with neutron scattering was used to suggest that the RNA was located in a central core of the subunit and the proteins mainly in the periphery, with virtually no separation between the centers of mass of protein and RNA. However, these findings are incompatible with the results of efforts to locate individual ribosomal proteins by immune electron microscopy and triangulation with interprotein distance measurements. The conflict between these two views is resolved in this report of small-angle neutron scattering measurements on 30S subunits with and without protein S1, and on subunits reconstituted from deuterated 16S RNA and unlabeled proteins. The results show that (i) the proteins and RNA are intermingled, with neither component dominating at the core or the periphery, and (ii) the spatial distribution of protein and RNA is asymmetrical, with a separation between their centers of mass of about 25 angstroms.

Are there proteins between the ribosomal subunits? Hot tritium bombardment experiments

The hot tritium bombardment technique [(1976) Dokl. Akad. Nauk SSSR 228, 1237-1238] was used for studying the surface localization of ribosomal proteins on Escherichia coli ribosomes. The degree of tritium labeling of proteins was considered as a measure of their exposure (surface localization). Proteins S1, S4, S7, S9 and/or S11, S12 and/or L20, S13, S18, S20, S21, L5, L6, L7/L12, L10, L11, L16, L17, L24, L26 and L27 were shown to be the most exposed on the ribosome surface. The sets of exposed ribosomal proteins on the surface of 70 S ribosomes, on the one hand, and the surfaces of 50 S and 30 S ribosomal subunits in the dissociated state, on the other, were compared. It was found that the dissociation of ribosomes into subunits did not result in exposure of additional ribosomal proteins. The conclusion was drawn that proteins are absent from the contacting surfaces of the ribosomal subunits.

Three-dimensional arrangement of the Escherichia coli 16 S ribosomal RNA

A model for the arrangement of the Escherichia coli 16 S ribosomal RNA in the 30 S ribosomal subunit is given. This model is based on the 16 S ribosomal RNA secondary structure, intramolecular RNA crosslinking results, protein-RNA interactions, and the locations of proteins within the 30 S subunit. These considerations allow placement of most of the RNA helices in approximate positions. The overall shape (that of an asymmetric Y) is very reminiscent of the description of the shape of the RNA made by direct determinations and is reasonably correlated to the appearance of the 30 S subunit. The identities of the three major secondary-structure domains of the 16 S ribosomal RNA are, for the most part, preserved. In addition, many close contacts between the 5' and middle RNA domains occur in the body of the particle. The 3'-terminal domain is situated in the central part of the model. This position corresponds to the region between the head and the platform structure in the 30 S subunit. The regions that represent the general locations of the messenger RNA and transfer RNA binding sites can be identified in the model.

Evidence that ribosomal protein S10 itself is a cellular component necessary for transcription antitermination by phage lambda N protein

Bacteriophage lambda N gene product acts to modify host RNA polymerase allowing the formation of a termination-resistant transcription apparatus. Previous studies have demonstrated that the nusE71 mutation that has altered the ribosomal protein S10 prevents N action in vivo. Using a coupled transcription-translation system, we demonstrate here that purified S10 protein as well as the 30S ribosomal subunit is sufficient to restore N activity in the nusE mutant extract, allowing antitermination of Rho-dependent and Rho-independent terminators. This provides direct biochemical evidence that the S10 protein itself is one of the cellular components necessary for the formation of an antitermination apparatus.

Comparative electron microscopic study on the location of ribosomal proteins S3 and S7 on the surface of the E. coli 30S subunit using monoclonal and conventional antibody

Mice were immunised with 30S subunits from E. coli and their spleen cells were fused with myeloma cells. From this fusion two monoclonal antibodies were obtained, one of which was shown to be specific for ribosomal protein S3, the other for ribosomal protein S7. The two monoclonal antibodies formed stable complexes with intact 30S subunits and were therefore used for the three-dimensional localisation of ribosomal proteins S3 and S7 on the surface of the E. coli small subunit by immuno electron microscopy. The antibody binding sites determined with the two monoclonal antibodies were found to lie in the same area as those obtained with conventional antibodies. Both proteins S3 and S7 are located on the head of the 30S subunit, close to the one-third/two-thirds partition. Protein S3 is located just above the small lobe, whereas protein S7 is located on the side of the large lobe.

Positions of proteins S14, S18 and S20 in the 30 S ribosomal subunit of Escherichia coli

A map of the 30 S ribosomal subunit is presented giving the positions of 15 of its 21 proteins. The components located in the map are S1, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12, S14, S15, S18 and S20.

Location of tRNA on the ribosome

Electron microscopy results of Lake [J. Mol. Biol. (1976) 105, 131-159] and Vasiliev et al. [FEBS Lett. (1983) 155, 167-172] suggest that the 70 S ribosome has an open pocket or a cavity at the base of the L7/L12 stalk of the 50 S subunit, on the side of the 30 S subunit opposite to its bulge or platform. It is this pocket that is proposed here to be the site for binding and retention of two L-shaped tRNA molecules on the ribosome. The model proposed is consistent with the facts about interactions of the protein L7/L12 with the elongation factors (EF-Tu and EF-G) involved in tRNA binding and translocation, as well as with the data available on the participation of proteins S3, S5, S10, S14 and S19 in the formation of tRNA sites.

Immunochemical accessibility of ribosomal protein S4 in the 30 S ribosome. The interaction of S4 with S5 and S12

The reactivity of protein S4-specific antibody preparations with 30 S ribosomal subunits and intermediates of in vitro subunit reconstitution has been characterized using a quantitative antibody binding assay. Anti-S4 antibody preparations did not react with native 30 S ribosomal subunits; however, they did react with various subunit assembly intermediates that lacked proteins S5 and S12. The inclusion of proteins S5 and S12 in reconstituted particles resulted in a large decrease in anti-S4 reactivity, and it was concluded that proteins S5 and S12 are primarily responsible for the masking of S4 antigenic determinants in the 30 S subunit. The effect of S5 and S12 on S4 accessibility is consistent with data from a variety of other approaches, suggesting that these proteins form a structural and functional domain in the small ribosomal subunit.

Ribosomal protein S4 is an internal protein: Localization by immunoelectron microscopy on protein-deficient subribosomal particles

The location of protein S4 in the small ribosomal subunit has been identified by immunoelectron microscopy. Although intact small subunits are not reactive with antibodies directed against protein S4, subribosomal particles reconstituted without proteins S5 and S12 are reactive. By using these "incomplete" subparticles, we have mapped the position of S4. It is located at a single site on the exterior (cytoplasmic) side of the subunit, at the partition that separates the one-third, or head, from two-thirds, or base, of the subunit. In this location, protein S4 is "beneath" proteins S5 and S12. All three proteins are members of a complex on, or near, the external surface of the small ribosomal subunit that plays an important role in regulation of translational fidelity.

A ribonucleoprotein fragment of the 30 S ribosome of E. coli containing two contiguous domains of the 16 S RNA

Ribonucleoprotein fragments of the 30 S ribosome of E. coli have been prepared by limited ribonuclease digestion and mild heating of the ribosome in a constant ionic environment. One such fragment has been described previously. A second electrophoretically homogeneous fragment has now been isolated and its RNA and protein moieties have been characterized. It contains the 5' half of the 16 S RNA, encompassing domains I and II except for the extreme 5' terminus and several small gaps. Seven proteins are present: S4, S5, S6, S8, S12, S15 and S20. The RNA binding sites of five of these proteins are known, and all are RNA sequences that are present in the fragment. Published neutron scattering and immuno-electron microscopic data indicate that six of the proteins are clustered together in a cross sectional slice through the center of the subunit. After deproteinization, the RNA moiety gives two bands in gel electrophoresis, one containing domains I and II and the other, essentially only domain II. The former, although larger, migrates faster in gel electrophoresis, indicating that RNA domains I and II interact with each other in such a way as to become more compact than domain II by itself.