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.     

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).     

A spectrophotometric study of the secondary structure of ribonucleic acid isolated from the smaller and larger ribosomal subparticles of rabbit reticulocytes

The spectrum of RNA from the smaller and larger subparticles of rabbit reticulocyte ribosomes was studied as a function of pH, ionic strength, urea concentration and temperature. It was inferred that both RNA species form short double-helical segments of not more than about 10 base-pairs in length. Not more than about 70% of the base residues may be located in double-helical segments. RNA from the larger subparticle is richer in guanine and cytosine residues and its secondary structure is the more stable. These conclusions are based on the use of double-helical RNA from virus-like particles and of unfractionated Escherichia coli tRNA as model systems.     

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.     

Ribosome structure determined by electron microscopy of Escherichia coli small subunits,large subunits and monomeric ribosomes

Unique, three-dimensional structures have been determined for Escherichia coli small subunits, large Subunits and monomeric ribosomes by electron microscopy of ribosomes and subunits and of antibody-labeled ribosomes and subunits.Small subunits orient on the carbon substrate with their long axes parallel to the plane of the carbon. In these projections the subunit is divided into a onethird and a two-thirds portion by a region of accumulated negative stain similar to that observed in eukaryotic small subunits. Four characteristic views, or projections, are readily recognized and correspond to orientations of approximately ?40 °, 0 °, +50 ° and +110 ° about the long axis of the subunit. Three of these have been described (Lake et al., 1974a; Lake & Kahan, 1975). The two most distinctive views are a quasi-symmetric view (0 °) that is characterized by an approximate line of mirror symmetry that coincides with the long axis of the subunit, and an asymmetric view (110 °) that is characterized by a concave and a convex subunit boundary. In the asymmetric projection, a platform or ledge is viewed “face-on”. The platform is attached to the lower two-thirds of the subunit just below the one-third/two-thirds partition. It is separated from the upper one-third of the subunit at the level of the partition and above the partition it forms a cleft approximately 30 to 40 Å wide, which has been suggested as the site of the codon-anticodon interaction (Lake & Kahan, 1975).Four characteristic views are presented for the large subunit. The most prominent of these, the quasi-symmetric view (θ = 90 °, φ = 0 °), is distinguished by a central protuberance located on a line of approximate mirror symmetry. The central protuberance is surrounded by projecting features inclined at about 50 ° on both sides of it. The smaller of these projections is rod-like, about 40 Å wide and approximately 100 Å long. The feature projecting from the other side of the central protuberance is shorter, more blunt and wider than the rod-like appendage. In another view approximately orthogonal to the quasi-symmetric projection, the asymmetric projection (θ = 10 °, φ = 90 °), the subunit profile is distinguished by a convex lower edge and an upper boundary which is indented by a notch. The subunit is separated, in projection, by the notch into two unequal regions. The smaller region comprises about 20% of the total projected density and consists of the central protuberance and the rod-like appendage.The profiles observed in fields of monomeric 70 S ribosomes result from superpositions of the 30 S and 50 S profiles. Two major views are observed, an overlap and a non-overlap view, corresponding to whether or not the profile of the small subunit overlaps that of the large subunit in the 70 S profile. The small subunit is oriented in the monomeric ribosome so that the platform is in contact with the large subunit. The central protuberance of the large subunit overlaps part of the upper one-third of the small subunit in the overlap view of 70 S ribosomes, although in three dimensions they are probably separated by 30 to 50 Å. A region of the small subunit comprising the platform, the cleft and part of the upper one-third, suggested to be the approximate binding site of IF3 and IF2 (Lake & Kalian, 1975), is located at the interface between the large and small subunits, in a region of the small subunit that is close to, but probably not in physical contact with, the large subunit.     

On the distribution and packing of RNA and protein ribosomes.

From the analysis of the measured radii of gyration of the RNA (Rg = 6.6 +/- 0.3 nm) and protein (Rg = 10.2 +/- 0.5 nm) components of the 50-S subparticle of Escherichia coli ribosomes it is concluded that proteins containing a large amount of hydrodynamically bound water are located on the periphery of the tightly packed RNA. We found that the common features of the measured X-ray scattering curves of the E. coli 70-S ribosome, its 30-S and 50-S subparticles and wheat 80-S ribosomes in the region of scattering angles corresponding to scattering vectors mu from 1 to 5 nm-1 reflect features of the RNA compact packing. A hypothesis is proposed that the compact packing of RNA helices in the range of Bragg distances of 4.5--2.0 nm is a general structural feature of all ribosomal particles.     

Reconstruction of the smaller subparticle of rabbit ribosomes from core-particle and split-protein fractions.

The smaller subparticle of rabbit reticulocyte ribosomes was shown to yield core-particle and split-protein fractions on treatment with 2.5 M-NH4Cl/61 mM-MgCl2. The core-particle fraction was inactive in poly(U)-directed polyphenylalanine synthesis, but activity was restored after recombination with the split-protein fraction. Optimum ionic conditions for the reconstruction of active subparticles were found to be 0.75 M-NH4Cl/19 mM-MgCl2 at 0 degrees C. Improved extents of reconstruction were obtained when the core-particles were isolated by methods that avoided pelleting. Core-particles isolated from subparticles pretreated with either proteinases or ribonucleases had diminished capacity to become re-activated.     

Properties of intraribosomal part of nascent polypeptide

This review analyzes the concept according to which the pathway of synthesized peptide from the ribosome peptidyl transferase center to the exit domain goes along the tunnel of the large subparticle. Experimental data on the accessibility of the nascent polypeptide chain to molecules of modifying agents and fluorescence quenchers are considered. Results of localization of the exit site for the nascent peptide on the ribosome surface, possible conformational states of the peptide, and its mobility and folding on the ribosome are analyzed. The analysis is based on the ribosomal tunnel parameters obtained using X-ray crystallography of whole ribosomes and large ribosomal subparticles. Special attention is given to data that do not fit in the concept of the “tunnel for peptide exit“ and to results already obtained before the reliable tunnel visualization using X-ray crystallography was achieved.     

A low-resolution model of crystalline methionyl-transfer RNA synthetase from Escherichia coli

When submitted to a controlled proteolysis by trypsin, native methionyl-tRNA synthetase from Escherichia coli (a dimer of molecular weight 172,000) yields a well-defined fragment of molecular weight 64,000 composed of one single polypeptide chain. This fragment retains full specificity towards methionine and tRNA^met, and has unimpaired activity in both the activation reaction and aminoacyl-tRNA formation. Crystals of this active fragment have been studied by X-ray crystallography and, using two isomorphous heavy-atom derivatives, a 4 Å electron density map has been calculated.The molecule appears as an elongated ellipsoid of overall dimensions 90 Å × 43 Å × 43 Å. It is clearly built of two parts separated by a large cleft. The volume of one of these “domains” is approximately twice that of the other; these results are consistent with our present knowledge of the chemistry of the protein.     

The Crystal Structure of Glutamine-binding Protein fromEscherichia coli

The crystal structure of the glutamine-binding protein (GlnBP) fromEscherichia coliin a ligand-free “open” conformational state has been determined by isomorphous replacement methods and refined to anR-value of 21.4% at 2.3 Å resolution. There are two molecules in the asymmetric unit, related by pseudo 4-fold screw symmetry. The refined model consists of 3587 non-hydrogen atoms from 440 residues (two monomers), and 159 water molecules. The structure has root-mean-square deviations of 0.013 Å from “deal” bond lengths and 1.5° from “ideal” bond angles.The GlnBP molecule has overall dimensions of approximately 60 Å × 40 Å × 35 Å and is made up of two domains (termed large and small), which exhibit a similar supersecondary structure, linked by two antiparallel β-strands. The small domain contains three α-helices and four parallel and one antiparallel β-strands. The large domain is similar to the small domain but contains two additional α-helices and three more short antiparallel β-strands. A comparison of the secondary structural motifs of GlnBP with those of other periplasmic binding proteins is discussed.A model of the “closed form” GlnBP-Gln complex has been proposed based on the crystal structures of the histidine-binding protein-His complex and “open form” GlnBP. This model has been successfully used as a search model in the crystal structure determination of the “closed form” GlnBP-Gln complex by molecular replacement methods. The model agrees remarkably well with the crystal structure of the Gln-GlnBP complex with root-mean-square deviation of 1.29 Å. Our study shows that, at least in our case, it is possible to predict one conformational state of a periplasmic binding protein from another conformational state of the protein. The glutamine-binding pockets of the model and the crystal structure are compared and the modeling technique is described.     

Mitochondrial and cytoplasmic ribosomes from mammalian tissues. Further characterization of ribosomal subunits and validity of buoyant-density methods for determination of the chemical composition and partial specific volume of ribonucleoprotein particles

1. At 0-4 degrees C mitochondrial ribosomes (55S) dissociate into 39S and 29S subunits after exposure to 300mm-K(+) in the presence of 3.0mm-Mg(2+). When these subunits are placed in a medium containing a lower concentration of K(+) ions (25mm), approx. 75% of the subparticles recombine giving 55S monomers. 2. After negative staining the large subunits (20.3nm width) usually show a roundish profile, whereas the small subunits (12nm width) show an elongated, often bipartite, profile. The dimensions of the 55S ribosomes are 25.5nmx20.0nmx21.0nm, indicating a volume ratio of mitochondrial to cytosol ribosomes of 1:1.5. 3. The 39S and 29S subunits obtained in high-salt media at 0-4 degrees C have a buoyant density of 1.45g/cm(3); from the rRNA content calculated from buoyant density and from the rRNA molecular weights it is confirmed that the two subparticles have weights of 2.0x10(6) daltons and 1.20x10(6) daltons; the weights of the two subunits of cytosol ribosomes are 2.67x10(6) and 1.30x10(6) daltons. 4. The validity of the isodensity-equilibrium-centrifugation methods used to calculate the chemical composition of ribosomes was reinvestigated; it is confirmed that (a) reaction of ribosomal subunits with 6.0% (v/v) formaldehyde at 0 degrees C is sufficient to fix the particles, so that they remain essentially stable after exposure to dodecyl sulphate or centrifugation in CsCl, and (b) the partial specific volume of ribosomal subunits is a simple additive function of the partial specific volumes of RNA and protein. The RNA content is linearly related to buoyant density by the equation RNA (% by wt.)=349.5-(471.2x1/rho(CsCl)), where 1/rho(CsCl)=[unk](RNP) (partial specific volume of ribonucleoprotein). 5. The nucleotide compositions of the two subunit rRNA species of mitochondrial ribosomes from rodents (42% and 43% G+C) are distinctly different from those of cytoplasmic ribosomes.     

Isolation and study of the properties of Streptococcus pyogenes ribosomes

Ribosomes from Streptococcus pyogenes, group A, strain 29 were studied. A comparison of different methods of ribosomal isolations has shown that the homogenous ribosomal samples can be obtained by the method of differential ultracentrifugation using tris-HCl buffer. The ribosomes of S. pyogenes had the sedimentation coefficient of 70S and consisted of 65% of protein and 35% of nucleic acids; the ribosomes dissociated into subparticles with the sedimentation coefficients of 50S and 30S under a low magnesium concentration. Thus the S. pyogenes ribosomes do not differ from the ribosomes of procaryotes. It was shown that the ratios of 70S, 50S and 30S ribosomal subparticles in the cells depend on the growth phase of S. pyogenes. The cells of the middle and the late logarithmic phase contained 50S and 30S particles in a stoichiometric ratio. In the cells of the late stationary growth phase there was a deficiency of 30S ribosomal subparticles which does not result from a loss during the isolation procedure, as it was already observed in the initial 30S fraction.     

Immunochemical analysis of the structure of eukaryotic ribosomes

Summary Antibodies were prepared in rabbits and sheep to rat liver ribosomes, ribosomal subunits, and to mixtures of proteins from the particles. The antisera were characterized by quantitative immunoprecipitation, by passive hemagglutination, by immunodiffusion on Ouchterlony plates, and by immunoelectrophoresis. While all the antisera contained antibodies specific for ribosomal proteins, none had precipitating antibodies against ribosomal RNA. Rat liver ribosomal proteins were more immunogenic in sheep than rabbits, and the large ribosomal subunit and its proteins were more immunogenic than those of the 40S subparticle. Antisera specific for one or the other ribosomal subunit could be prepared; thus it is unlikely that there are antigenic determinants common to the proteins of the two subunits. When ribosomes, ribosomal subunits, or mixtures of proteins were used as antigens the sera contained antibodies directed against a large number of the ribosomal proteins.Abbreviations TP total proteins—used to designate mixtures of proteins from ribosomal particles, hence TP80 is a mixtures of all the proteins from 80S ribosomes - TP60 the proteins from 60S subunits - TP40 the proteins from 40S particles     

Structure of ribosomes and ribosomal subunits of Drosophila

Summary The ultrastructure of Drosophila melanogaster cytoplasmic ribosomal subunits and monomers have been examined by electron microscopy. The Drosophila ribosomal structures are compared to those determined for other eucaryotes and E. coli. Negatively contrasted images of 60S subunits are seen in the most frequent view to be approximately round particles about 280 Å in diameter. About 35% of the particles present a single prominent projection which we call the 60S peak. The peak emanates from a flattened region of the 60S subunit. The maximum observed length of the 60S peak is approximately 90Å. The Drosophila 60S peak is highly reminiscent of the E. coli L7/L12 stalk. The Drosophila 40S subunit is an elongated, slightly bent particle which measures 280×170×160 Å. It bears a strong resemblance to small ribosomal subunits of other eucaryotes and is strikingly similar to the E. coli 30S subunit. Micrographs of 80S monomeric ribosomes show the long axis of the 40S to be parallel and in apparent contact with the flattened region of 60S subunit. The 60S peak appears to bisect the long axis of the 40S subunit. The 40S subunit seems to be oriented in the monomeric ribosome so that the 40S projection is toward the body of the large subunit. Comparison of our data with similar studies in different organisms indicates that the eucaryotic large ribosomal subunits exhibit morphological heterogeneity while the small subunits remain remarkably similar.     

Inelastic laser light scattering and particle size of detergent-treated microsomes

Using inelastic laser light scattering we have determined the hydrodynamic diameters of a variety of hepatic microsomal preparations. Whole microsomes have a diameter of 3200 Å. Treatment of microsomes with deoxycholate or cholate and chromatography on DEAE-cellulose give three protein fractions: a “non-absorbed” fraction with particles 2650 Å in diameter, cytochrome P-420 1700 Å in diameter and cytochrome c reductase 760 Å in diameter. Preparation of cytochrome P-450 by (NH₄)₂SO₄ precipitation from cholate solution gives particles 640 Å in diameter. All of these sizes are much too large to represent single molecular species, indicating that these fractions are aggregates of membrane proteins with varying concentrations of lipids.     

Stoichiometry of GTP hydrolysis during peptide synthesis on the ribosome. I. Factor-independent GTPase and ATPase of ribosomal preparations

It has been found that preparations of Escherichia coli (MRE-600) ribosomes can display GTPase and ATPase activities independent of elongation factors EF-Tu and EF-G. The GTPase and ATPase are localized on ribosomal 50S subparticles, whereas 30S subparticles are free of the activities and do not stimulate them upon association with the 50S subparticles to form complete ribosomes. The GTPase and ATPase can be removed from the ribosomes and their 50S subparticles by treatment with 1 M NH4Cl or 50% ethanol in the cold. Ribosomal preparations freed from the factor-independent GTPase and ATPase retain their basic functional features. The data obtained do not permit to solve finally whether the factor-independent GTPase and ATPase revealed are components of ribosomes or represent a contamination rather firmly bound to the ribosomes. However, in any case this finding can contribute to an uncoupled hydrolysis of GTP and should be considered when studying the stoichiometry of triphosphate expenditure in the process of ribosomal protein synthesis.     

Scanning electron microscope observations of the organic matrix in the otolith of the teleost fish Fundulus heteroclitus (Linnaeus) and Tilapia nilotica (Linnaeus)

Scanning electron microscope observations of sagitta otoliths of Fundulus heteroclitus (Linnaeus) and Tilapia nilotica (Linnaeus) have revealed that the “discontinuous zone” is a narrow band of organic matrix consisting of fibers ≈900 Å thick, that in turn are composed of thin fibers ≈200 Å thick. The “incremental zone” is the crystalline layer with crystals elongated perpendicular to the otolith periphery that are usually terminated at the discontinuous zones. The crystals are embedded in organic matrix fibers that appear similar to and continuous with the fibers of the discontinuous zones. Frequently, these fibers aggregate into matrix sheets. Based on these findings, a possible process of otolith formation is proposed.     

Freeze-fracture study of water-soluble,standard proteins and of detergent-solubilized forms of sarcoplasmic reticulum Ca2+-ATPase

Conventional freeze-fracture electron microscopy was used to study water-soluble proteins and different forms of Ca²⁺-ATPase-detergent complexes. Freeze-fracture images of solutions containing proteins larger than myoglobin showed the presence of distinct, randomly dispersed particles on smooth fracture surfaces. The distribution of sizes of these particles was close to Gaussian, with a mean size which was correlated to the Stokes diameter. Monomeric Ca²⁺-ATPase from sarcoplasmic reticulum, solubilized by deoxycholate or a non-ionic detergent, showed a bimodal distribution of particles sizes. Even more complex distributions were found for dimeric and trimeric preparations of Ca²⁺-ATPase. The results can be interpreted on the assumption that the Ca²⁺-ATPase molecule is elongated, with an overall length of about 110 Å and a width in its largest part of about 75 Å. It is concluded on the basis of the presented results that freeze-fracture electron microscopy can be successfully used for morphological studies of protein molecules in solution.     

Resistance of the peptidyltransferase centre of rabbit ribosomes to attack by nucleases and proteinases.

Larger ribosomal subparticles (L-subparticles) of rabbit ribosomes were treated with either ribonucleases (I or T1) or proteinases (trypsin or chymotrypsin), and their capacity to function in poly(U)-directed polyphenylalanine synthesis and in the puromycin reaction was investigated. The effects of pretreatment of L-subparticles on the reconstruction of active subparticles from core-particles derived by treatment with 2.75 M-NH4Cl/69 mM-MgCl2 and split-protein fractions were also examined. The protein moiety of proteinase-treated L-subparticles was analysed by one-dimensional sodium dodecyl sulphate/polyacrylamide- and two-dimensional polyacrylamide-gel electrophoresis. The introduction of 16--100 scissions in the RNA moiety had no effect on the activity of the L-subparticles in polyphenylalanine synthesis, and there was no effect on the stability of L-subparticles to high-salt shock treatment and a marginal effect on the reconstruction of L-subparticles from high-salt-shock core-particles and split-protein fractions. In contrast, L-subparticles treated with low amounts of trypsin (0.56 ng of trypsin/microgram of L-subparticle) were inactive in polyphenylalanine synthesis, and their capacity to function in partial-reconstruction experiments was diminished. Activity in the puromycin reaction was increased by 70% as a result of trypsin treatment (280 ng of trypsin/microgram of L-subparticle). At least two of the acidic proteins implicated in the translocation function were not affected by trypsin treatment. Trypsin-treated L-subparticles had lost their capacity to bind the smaller ribosomal subparticle (S-subparticle). The protein(s) needed for S-subparticle binding were shown to be present in high-salt-shock cores. At least six proteins associated with the core-particles were attack during trypsin treatment of L-subparticles. An examination of L-subparticles isolated from trypsin-treated polyribosomes showed that the amount of trypsin necessary to decrease the activity of the subparticle by 50% was about twice that needed in the treatment of L-subparticles alone. The largest protein of rabbit L-subparticles (approx. 51 000 daltons) was cleaved in a stepwise fashion by trypsin to fragments of approx. 40 000 daltons. This protein was also cleaved by chymotrypsin.