Identification of components of the streptomycin-binding center ofE. coli MRE 600 ribosomes by photo-affinity labelling

Summary The [H³]-labelled photo-activated analog of streptomycin (photo-Sm) is obtained as a result of the streptomycin reaction with 2-nitro, 4-azidobenzoylhydrazide and subsequent reduction with NaBH₄ ³. The analog retains the functional activity of the initial antibiotic as judged by two criteria: (1) it binds only to the 30S subparticle of ribosomes and (2) it inhibits the factor-free (“non-enzymatic”) PCMB-stimulated polyU-dependent system of translation (Gavrilova and Spirin, 1971). After irradiation of the reaction mixture containing photo-Sm and either the 30S or 50S subparticles of ribosomes under similar conditions, the analog covalently binds chiefly to the 30S subparticle. Irradiation of the photo-Sm mixture with whole 70S ribosomes leads to a uniform distribution of a covalently bound label among the subparticles. A comparison of the effects obtained allows the conclusion that the analog is located on the interface of the ribosomal subparticles. In the 30S subparticle the photo-Sm attacks mainly the protein component (more than 95% of all the covalently bound label). The proteins labelled by photo-reaction are identified as S7 (main), S14 (additional) and S16/S17 (minor).     

Joint use of light, X-ray and neutron scattering for investigation of RNA and protein mutual distribution within the 50S subparticle of E. coli ribosomes.

The values of the RNA and protein radius of gyration obtained in these studies corroborate the conclusion reported earlier [1] that on average the RNA is nearer to the center of the particle than is the protein. (It should be noted for comparison that the minimal Rg value of the RNA corresponding to its dense packing as a sphere in the center of the 52S subparticle is 49 A.) Moreover, such a great difference in the radii of gyration of RNA and protein implies a definite scheme of mutual RNA and protein arrangement in the 50S subparticle -- namely the distribution of the greater mass of proteins on the RNA surface.     

Structure of Rpn10 and Its Interactions with Polyubiquitin Chains and the Proteasome Subunit Rpn12

Schizosaccharomyces pombe Rpn10 (SpRpn10) is a proteasomal ubiquitin (Ub) receptor located within the 19 S regulatory particle where it binds to subunits of both the base and lid subparticles. We have solved the structure of full-length SpRpn10 by determining the crystal structure of the von Willebrand factor type A domain and characterizing the full-length protein by NMR. We demonstrate that the single Ub-interacting motif (UIM) of SpRpn10 forms a 1:1 complex with Lys⁴⁸-linked diUb, which it binds selectively over monoUb and Lys⁶³-linked diUb. We further show that the SpRpn10 UIM binds to SpRpn12, a subunit of the lid subparticle, with an affinity comparable with Lys⁴⁸-linked diUb. This is the first observation of a UIM binding other than a Ub fold and suggests that SpRpn12 could modulate the activity of SpRpn10 as a proteasomal Ub receptor.     

Predict prokaryotic proteins through detecting N-formylmethionine residues in protein sequences using support vector machine

Identifying prokaryotes in silico is commonly based on DNA sequences. In experiments where DNA sequences may not be immediately available, we need to have a different approach to detect prokaryotes based on RNA or protein sequences. N-formylmethionine (fMet) is known as a typical characteristic of prokaryotes. A web tool has been implemented here for predicting prokaryotes through detecting the N-formylmethionine residues in protein sequences. The predictor is constructed using support vector machine. An online predictor has been implemented using Python. The implemented predictor is able to achieve the total prediction accuracy 80% with the specificity 80% and the sensitivity 81%.     

Isolation of all proteins from the 50S subparticles of ribosomes of Escherichia coli

The paper proposes a method of preparative isolation of all proteins from the 50S subparticle of E. coli ribosomes. The method is based on (1) preliminary fractionation into protein groups and ribonucleoprotein particles by a consecutive treatment of the 50S particles with increasing LiCl concentrations, and (2) chromatographic separation of protein groups on DE- and CM-cellulose and gel-filtration of separate fractions. The method allows to obtain any protein required for studies in preparative amounts avoiding many chromatographic stages. A detailed scheme of isolation of all proteins is given together with quantitative data of yields of individual proteins calculated per 6 g of the 50S subparticles.     

Characterization of methylated neutral amino acids from Escherichia coli ribosomes.

The methylated neutral amino acids from both 30S and 50S ribosomal subunits of an Escherichia coli K strain were characterized. The 50S ribosomal subunit contains three methylated neutral amino acids: N-monomethylalanine, N-monomethylmethionine, and an as yet unidentified methylated amino acid found in protein L11. Both N-monomethylalanine and N-monomethylmethionine were found in protein L33. The amount of N-monomethylmethionine in this protein, however, is variable but not more than 0.25 molecules per protein. Thus protein L33 from this E. coli K strain has heterogeneity in its N-terminal amino acid and can start with either N-monomethylalanine or N-monomethylmethionine. The N-monomethylmethionine residue was not derived from the reduction of N-formylmethionine in the protein. The 30S ribosomal subunit contains only one methylated neutral amino acid: N-monomethylalanine.     

Re-activation of the peptidyltransferase centre of rabbit reticulocyte ribosomes after inactivation by exposure to low concentrations of magnesium ion.

1. The larger subrivosomal particles of rabbit reticulocytes retained full activity in the puromycin reaction and in poly(U)-directed polyphenylalanine synthesis after 4h at 0 degrees C when buffered 0.5M-NH4Cl/10-30mM-MgCl2 was the solvent. 2. Activity in the puromycin reaction was diminished to approx 10% after 15-30 min at 0 degrees C when the concentration of MgCl2 was lowered to 2mM. 3. Activity was not restored when the concentration of MgCl2 was raised from 2mM to 10-30 mM at 0 degrees C. However, activity was recovered as measured by both assay systems when the ribosome fraction was heated to 37 degrees C at the higher concentrations of MgCl2. 4. Recovery of activity was noted during the course of the polyphenylalanine synthesis in 50 mM-KCl/5mM-MgCl2/25mM-Tris/HCl, pH 7.6, at 37 degrees C. Re-activation was slow at 20 degrees C and below. 5. No more than about 5% of the protein moiety of the subparticle was lost in 0.5M-NH4Cl on decreasing MgCl2 concentration from 10mM to 2mM. No proteins were detected in the supernatant fractions by gel electrophoresis after ribosomes were separated by differential centrifugation. The supernatant fraction was not essential for the recovery of activity. However, at higher (e.g. 1M) concentrations of NH4Cl, proteins were split from the subparticle. 6. The loss and regain of activity found on lowering and restoring the concentration of MgCl2 at 0.5M-NH4Cl appears to arise from a conformational change that does not seem to be associated with a loss and regain of particular proteins. 7. A 2% decrease in E260 was noticed when the concentration of Mg2+ was restored, and the change in the spectrum indicated a net increase of approx. 100A-U base-pairs per subribosomal particle. 8. When the concentration of Mg2+ was restored, S20,W of the subparticle remained at 52+/- 1S until the sample was incubated at 37 degrees C when S20,W increased to 56 +/- 1S compared with the value of 58 +/- 1S for the subparticle as originally isolated.     

Kinetics of specific (codon-dependent) binding of aminoacyl-tRNA to the 30S ribosomal subunit under different medium conditions]

It was shown that the increase of Mg2+ ions concentration in the medium from 0,01 M to 0,03 M speeds up the formation of a codon-dependent complex between 14C-Phe-tRNA and the 30S ribosomal subparticle. Under high MgCl2 concentration (0,02 M) the increase of NH4Cl concentration also accelerates the specific binding of 14C-Phe-tRNA to the 30S subparticle. In the presence of 0,005 M MgCl2 0,5 M urea significantly decreases the rate of the specific binding. 0,5 M ethanol does not have any noticeable effect on the kinetics of the reaction.     

Elongation factor G protects a nuclease-sensitive site of 23 S RNA within the ribosome

Elongation factor G is shown to protect the nuclease splitting off the 3′ -terminal 11 S fragment from the 23 S RNA within the ribosomal 50 S subparticle.     

Study of the internal structure of Escherichia coli ribosomes by neutron and x-ray scattering.

Neutron scattering curves of the small and large subparticles of Escherichia coli ribosomes are presented over a wide range of scattering angles and for several contrasts. It was verified that the native ribosome structure was not affected by ²H₂O in the buffer. The reliability of the neutron scattering curves, obtained in H₂O buffer, was established by X-ray scattering experiments on the same material.The non-homogeneous distribution of RNA and protein in the subparticles of E. coli ribosomes is confirmed, with RNA predominantly within the particle and protein predominantly on its periphery. The distances between the centres of gravity of the RNA and protein components do not exceed 25 Å and 30 Å, in the large and small subparticles, respectively.The volume occupied by the RNA within the large and small subparticles is determined. The ratio of the “dry” volume of the RNA to the occupied volume is found to be 0.56; it is the same in both subparticles. Such packing of RNA is characteristic of single helices of ribosomal RNA at their crystallization and of the helices in transfer RNA crystals. A conclusion is drawn that RNA in ribosomes is in a similar state.Experimental scattering curves for the small subparticle depend significantly on the contrast in the angular region in which the scattering is mainly determined by the particle shape. The scattering curve, as infinite contrast is approached, is similar to that calculated for the particle as observed by electron microscopy. Thus, the long-existing contradiction between electron microscopy data (an elonggated particle with an axial ratio 2:1) and X-ray data (an oblate particle with an axial ratio 1:3.5), concerning the overall shape of the 30 S subparticle, is settled in favour of electron microscopy. The experimental neutron scattering curve of RNA within the small subparticle is well-described by the V-like RNA model proposed recently by Vasiliev et al. (1978).Experimental data are given to support the hypothesis that the maxima in the X-ray scattering curves, in the region of scattering angles corresponding to Bragg distances of 90 to 20 Å, arise from the ribosomal RNA component alone. It is shown that the prominence of the peaks in this region of the scattering curve depends only on the scattering fraction of the RNA component. The scattering fraction can be changed both by using the “native contrast” (ribosomal particles containing different amounts of protein) and by varying the solvent composition. The maxima are most pronounced where the RNA scattering fraction is highest or in solvents where the protein density is matched by the solvent. The scattering vectors of the maxima in the X-ray and neutron scattering curves, however, remain unchanged. This allows us to propose the tight packing of RNA as a common principle for the structural arrangement of RNA in ribosomes.     

RNA-protein interactions in the ribosome. II. Binding of ribosomal proteins to isolated fragments of the 16 S RNA

Specific fragments of the 16 S ribosomal RNA of Escherichia coli have been isolated and tested for their ability to interact with proteins of the 30 S ribosomal subunit. The 12 S RNA, a 900-nucleotide fragment derived from the 5′-terminal portion of the 16 S RNA, was shown to form specific complexes with proteins S4, S8, S15, and S20. The stoichiometry of binding at saturation was determined in each case. Interaction between the 12 S RNA and protein fraction $\text{S}\text{16}\text{S}\text{17}$ was detected in the presence of S4, S8, S15 and S20; only these proteins were able to bind to this fragment, even when all 21 proteins of the 30 S subunit were added to the reaction mixture. Protein S4 also interacted specifically with the 9 S RNA, a fragment of 500 nucleotides that corresponds to the 5′-terminal third of the 16 S RNA, and protein S15 bound independently to the 4 S RNA, a fragment containing 140 nucleotides situated toward the middle of the RNA molecule. None of the proteins interacted with the 600-nucleotide 8 S fragment that arose from the 3′-end of the 16 S RNA.When the 16 S RNA was incubated with an unfractionated mixture of 30 S subunit proteins at 0 °C, 10 to 12 of the proteins interacted with the ribosomal RNA to form the reconstitution intermediate (RI) particle. Limited hydrolysis of this particle with T₁ ribonuclease yielded 14 S and 8 S subparticles whose RNA components were indistinguishable from the 12 S and 8 S RNAs isolated from digests of free 16 S RNA. The 14 S subparticle contained proteins S6 and S18 in addition to the RNA-binding proteins S4, S8, S15, S20 and $\text{S}\text{16}\text{S}\text{17}$. The 8 S subparticle contained proteins S7, S9, S13 and S19. These findings serve to localize the sites at which proteins incapable of independent interaction with 16 S RNA are fixed during the early stages of 30 S subunit assembly.     

Possibility of internal organization of RNA and proteins in ribosomal subparticles. A structural model of Escherichia coli 30S ribosomal subparticle]

The hypothetic model of reciprocal spatial arrangement of 18 from 21 proteins in the E. coli 30S ribosomal subparticle is suggested. The model is based on conception of the 16S R-A molecule macrostrand which is the right superhelix in the subparticle composition. Macrohelix's biopolarity against single-stranded sites of RNA and its small width result in that proteins binding with single-stranded RNA organized in chain, one-number sequence. The double helixes uniting the corresponding one single-stranded sites of RNA play the role of rigid transmission between them. So, in the course of subparticles reconstruction from RNA and proteins the spatially uncoupled proteins can interact without its direct contact. The model takes into consideration the vast amount of information.     

Initiation of protein synthesis in bacillus subtilis in the presence of trimethoprim or aminopterin.

Initiation of protein synthesis has been studied in the presence of the tetrahydrofolic acid analogues trimethoprim or aminopterin in Bacillus subtilis. This bacterium can grow in the presence of the inhibitors, when the medium is supplemented with the low molecular weight products of tetrahydrofolate-dependent pathways. In an attempt to show whether formylation of initiator tRNA is a prerequisite for the iniation of protein synthesis in procaryotic cells, the amount of N-formylmethionine in tRNA and in protein has been determined. The level of formylation of methionyl-tRNA was found to be 70% in control cells and approximately 2% in inhibitor-treated cells. The content of formyl groups in protein has also been found to be drastically reduced. Trimethoprim or aminopterin did not alter the amount of tRNAMet nor the degree of aminoacylation of tRNAMet in vivo. These results indicate that in B. subtilis inititation of protein synthesis is possible without prior formylation of initiator tRNA.     

Isolation of eukaryotic ribosomal proteins: purification and characterization of S25 and L16.

Proteins were extracted from rat liver ribosomal subunits with ethanol and ammonium chloride. The extract from the 40S subunit contained mainly S25, but smaller amounts of a number of other proteins were found as well; the extract from the 60S subparticle had L16 in addition to P1, P2, S25, and several other proteins. S25 and L16 had not been purified before. The former was isolated from the ethanol-ammonium chloride extract by stepwise elution from carboxymethylcellulose with LiCl, chromatography on phosphocellulose, and filtration through Sephadex G-75; L16 was purified by elution from carboxymethylcellulose with LiCl (in steps). The molecular weight of the two proteins was estimated by polyacrylamide gel electrophoresis in sodium dodecyl sulfate; and amino acid composition was determined also.     

Isolation and structural properties of membrane-bound Na+,K+- adenosine triphosphatase from pig kidney]

A technique for isolation of large amounts of homogeneous Na+, K+-ATPase lipid-protein complex from pig kindney has been developed. The purity of the preparation as determined by the protein component is 96-98%, the large to small subparticle ratio being 4 : 1. The protein and lipid parts of the preparation have approximately the same mass. The enzyme activity is 1600-1900 mcmoles of inorganic phosphate released per mg of protein per hour. The protein secondary structure in a heavy water solution has been studied by infrared spectroscopy in the region of the main amide bands. It has been shown that about 20% of the peptide groups form highly ordered alpha-helical regions and about 25% are found in the pleated sheet structure with an antiparallel packing of the chains. The regions with a regular structure are mainly located in the protein component regions, inaccessible for water and are presumably involved in the formation of the hydrophobic core of the molecule. The major part of the protein structure (approximately 55%) is non-ordered and is easily accessible for water molecules.     

Characterization of ribonucleoprotein subparticles from 50 S ribosomal subunits of Escherichia coli.

Large ribonucleoprotein subparticles were recovered upon ribonuclease digestion of the 50 S ribosomal subunits of Escherichia coli, partially deproteinized by LiCl. Both their RNA and their protein compositions were analysed. The subunits, treated with LiCl at a concentration of 5.5 m, released an homogeneous subparticle containing proteins L₃, L₄, L₁₃, L₁₇, L₂₂ and L₂₉, about 70% of the 13 S fragment of 23 S RNA and about 50% of the 18 S one. Slightly larger species of subparticles were obtained from 50 S subunits treated with LiCl at concentrations between 3 m and 5 m; they contained in addition proteins L₂₀, L₂₁ and L₂₃ or L₂, L₁₄, L₂₀, L₂₁ and L₂₃ and a few small 23 S RNA fragments. No large subparticle was recovered from the 6 m-LiCl-treated 50 S subunits which contain only proteins L₃, L₁₃ and L₁₇. These LiCl subparticles were compared with those obtained from intact, unfolded and sodium doecyl sulphatetreated 50 S subunits.These studies reveal that in the presence of 0.10 m-magnesium acetate there is a very compact area within 50 S subunits consisting of proteins L₃, L₄, L₁₃, L₁₇, L₂₂ and L₂₉ and of about 60% of 23 S RNA; this area probably has an essential structural role. The results also show that 23 S RNA has a more folded conformation when within the 50 S subunit than when isolated, this conformation being stabilized by some of the 50 S proteins, in particular proteins L₄, L₂₂, L₂₀ and L₂₁. Finally these data permit a more definite localization of the primary and/or secondary binding sites of proteins L₂, L₃, L₄, L₁₄, L₁₇, L₂₀, L₂₁ and L₂₂ on 23 S RNA.     

Mitochondrial RNA and protein synthesis in enucleated African green monkey cells

The behavior of extramitochondrial protein synthesis and of mitochondrial RNA and protein synthesis was examined in the cytoplasts of African green monkey kidney cells (TC-7 subline) at different times following enucleation by cytochalasin B. The rate of incorporation of [³H]isoleucine into protein of the soluble cytoplasmic fraction decreased in an approximately exponential fashion, with a half-life of about five hours, during the first 26 hours after enucleation. Discrete mitochondrial 16 S, 12 S and 4 S RNA components were identified among the products of cytoplast RNA synthesis. The rates of [³H]uridine incorporation into the 16 and 12 S RNA components as well as into total RNA declined progressively after enucleation to a barely detectable level by the 20th hour. By contrast, the rate of chloramphenicol-sensitive [³H]isoleucine incorporation into protein (due to mitochondrial protein synthesis) did not undergo a substantial decline for at least 20 hours in TC-7 cytoplasts; instead, a reproducible transient stimulation occurred in the first hours following enucleation. The products of mitochondrial protein synthesis pulse-labeled in nucleated cells and in cytoplasts 24 hours after enucleation exhibited similar electrophoretic profiles.     

Protein synthesis of the sponge Geodia cydonium: characterization of the system

The ribosomal population of the sponge Geodia cydonium has been examined. The monosomes have a sedimentation constant of 80 S, the sizes of the subunits are approximately 60 S and 45 S respectively. The polyribosomes contain up to 40 ribosomal units. Cell free protein synthesizing systems (cell homogenate as well as reconstituted system) have been prepared and characterized with respect to Mg²⁺, KCI and ATP concentrations, temperature, pH and time course of the reaction. In the cell-free system and in the cellular system the protein biosynthesis is inhibited by chloramphenicol. It is not affected by cycloheximide.