A purified nucleoprotein fragment of the 30 S ribosomal subunit of Escherichia coli

A ‘13 S’ nucleoprotein fragment was isolated from a nuclease digest of Escherichia coli 30-S ribosomal subunits and purified to gel electrophoretic homogeneity. It contained two polynucleotides, of about 1.1 · 10⁵ and 2.5 · 10⁴ daltons, which separated when the fragment was deproteinized. The major protein components were S4, S7 and S9/11, with S15, S16, S18, S19 and S20 present in reduced amount.     

A large nucleoprotein fragment of the 50-S ribosomal subunit of Escherichia coli.

A large nucleoprotein fragment was isolated from a nuclease digest of Escherichia coli 50-S ribosomes and purified to gel electrophoretic homogeneity. Conditions were employed under which the fragmentation pattern was reproducible and the various fragment fractions were stable and maintained their sedimentation and electrophoretic properties throughout the several preparative and analytical procedures used. Fractions that appeared homogeneous in sucrose gradient centrifugation were found to be heterogeneous by gel electrophoresis. The large fragment was purified to homogeneity by preparative gel electrophoresis. It contained 21 proteins, the 5-S RNA, and two large oligonucleotides which together total about two thirds the molecular weight of the 23-S RNA. Because it can be prepared reproducibly in large quantities and because of its size and stability, the fragment appears suitable for functional and structural studies and as the starting material for further fractionation. An important contributing factor to the observed stability and reproducibility was the maintenance of an unchanging ionic environment. A single buffer was employed throughout all the procedures, and the fragments produced by nuclease digestion were dissociated from each other by heat rather than by changing the medium.     

All-atom homology model of the Escherichia coli 30S ribosomal subunit

Understanding the structural basis of ribosomal function requires close comparison between biochemical and structural data. Although a large amount of biochemical data are available for the Escherichia coli ribosome, the structure has not been solved to atomic resolution. Using a new RNA homology procedure, we have modeled the all-atom structure of the E. coli 30S ribosomal subunit. We find that the tertiary structure of the ribosome core, including the A-, P- and E-sites, is highly conserved. The hypervariable regions in our structure, which differ from the structure of the 30S ribosomal subunit from Thermus thermophilus, are consistent with the cryo-EM map of the E. coli ribosome.     

Structural studies on the 30 S ribosomal subunit from Escherichia coli

Small-angle X-ray scattering curves computed for various 30 S subunit structures have been compared with the experimental scattering curve. The curve from the 30 S subunit is best approximated by that calculated for a 1:3.6:3.6 ellipsoidal structure. The rather prolate ellipsoidal model suggested by recent electron microscope studies gives a scattering curve considerably different from the 30 S curve, suggesting that the electron microscope model is not that found in solution. Analysis of the more extended portions of the experimental scattering curve suggests some internal structure. A model is proposed that contains RNA and protein in positions such that the calculated scattering curve shows more extensive, yet similar internal structure. Resultant constraints on the structure of the 30 S subunit in solution are given.     

Position of protein S1 in the 30 S ribosomal subunit of Escherichia coli

The results of neutron distance measurement involving ribosomal protein S1 from Escherichia coli are reported. These data provide a position for S1 on the small ribosomal subunit. They also indicate that S1, bound to the ribosome, has a radius of gyration of 60 to 65 Å, suggesting that its axial ratio in the bound state is similar to that it has as a free molecule in solution; namely, 10: 1. The implications of these results for our understanding of the mode of action of S1 are discussed.     

Evidence that Escherichia coli 30 S ribosomal subunit populations are conformationally heterogeneous.

We have estimated the number of sites on each protein of the 30 S ribosome which are accessible to chemical iodination. First, the total number of iodinatable sites was determined for the intact 30 S ribosome. The proteins were extracted, separated and the relative distribution of iodine in each protein determined. This distribution of iodine divided into the total sites per ribosome gave an estimate of the number of sites per individual protein.Second, the iodinated proteins were purified and their trypsin digestion products separated. The number of radioactive peptides was taken as a measure of the number of sites on that protein open to the iodination reaction. The number of iodinatable sites for each protein was found to be radically different by the two methods. In almost all cases, the number of unique, radioactively labeled peptides, derived from a given 30 S protein, far exceeded the total incorporation into that protein. We suggest that the best explanation for this unexpected discrepancy is that the 30 S ribosome population we used in these experiments is heterogeneous in its topography.In addition we have compared the topography by the chemical iodination procedure for ribosomes in two different conformations: active and inactive (see Zamir et al., 1971). We have found very little change in the chemical reactivity of the proteins when the ribosomes are in the two different conformations. The most notable changes involve proteins S10, $\text{S}\text{18}\text{S}\text{19}$ and especially $\text{S}\text{12}\text{S}\text{13}$.     

The conformation of 16S RNA in the 30S ribosomal subunit from Escherichia coli.

The digestion of E. coli 16S RNA with a single-strand-specific nuclease produced two fractions separable by gel filtration. One fraction was small oligonucleotides, the other, comprising 67.5% of the total RNA, was highly structured double helical fragments of mol. wt. 7,600. There are thus about 44 helical loops of average size corresponding to 12 base pairs in each 16S RNA. 10% of the RNA could be digested from native 30S subunits. Nuclease attack was primarily in the intraloop single-stranded region but two major sites of attack were located in the interloop single-stranded regions. Nuclease digestion of unfolded subunits produced three classes of fragments, two of which, comprising 80% of the total RNA, were identical to fragments from 16S RNA. The third, consisting of 20% RNA, together with an equal weight of peotein, was a resistant core (sedimentation coefficient 7S).     

Crosslinking studies on the organization of the 16 S ribosomal RNA within the 30 S Escherichia coli ribosomal subunit.

The location and frequency of RNA crosslinks induced by photoreaction of hydroxymethyltrimethylpsoralen with 30 S Escherichia coli ribosomal subunits have been determined by electron microscopy. At least seven distinct crosslinks between regions distant in the 16 S rRNA primary structure are seen in the inactive conformation of the 30 S particle. All correspond to crosslinked features seen when the free 16 S rRNA is treated with hydroxymethyltrimethylpsoralen. The most frequently observed crosslink occurs between residues near one end of the molecule and residues about 600 nucleotides away to generate a loop of 570 bases. The size and orientation of this feature indicate it corresponds to the crosslinked feature located at the 3′ end of free 16 S rRNA.When active 30 S particles are crosslinked in 5 mm-Mg²⁺, six of the seven features seen in the inactive 30 S particle can still be detected. However, the frequency of several of the features, and particularly the 570-base loop feature, is dramatically decreased. This suggests that the long-range contacts that lead to these crosslinks are either absent or inaccessible in the active conformation. Crosslinking results in some loss of functional activities of the 30 S particle. This is consistent with the notion that the presence of the crosslink that generates the 570-base loop traps the subunit in an inactive form, which cannot associate with 50 S particles.The arrangement of the interacting regions crosslinked by hydroxymethyltrimethylpsoralen suggests that the RNA may be organized into three general domains. A striking feature of the Crosslinking pattern is that three of the seven products involve regions near the 3′ end of the 16 S rRNA. These serve to tie together large sections of rRNA. Thus structural changes at the 3′ end could, in principle, be felt through the entire 30 S particle.     

Structure of the Escherichia coli 50 S ribosomal subunit

Freeze-dried and shadowed Escherichia coli 50 S ribosomal subunits have been examined by electron microscopy and a model of the subunit has been constructed. High resolution shadow casting has enabled us to determine independently the absolute hand of the subunit and to reveal some new structural features.     

The Escherichia coli 30S ribosomal subunit; an optimized three-dimensional fit between the ribosomal proteins and the 16S RNA.

We have generated a computerized fit between the 3-dimensional map of the E.coli 30S ribosomal proteins, as determined by neutron scattering, and the recently published 3-dimensional model for the 16S RNA. To achieve this, the framework of coordinates for RNA-protein cross-link sites on the phosphate backbone in the RNA model was related to the corresponding framework of coordinates for the mass centres of the proteins by a least squares fitting procedure. The resulting structure, displayed on a computer graphics system, gives the first complete picture of the E.coli 30S ribosomal subunit showing both the proteins and the double-helical regions of the RNA. The root mean square distance between cross-link sites and protein centres is 32 A. The position of the mass centre of the combined double-helical regions was calculated from the model and compared with the position of the mass centre of the complete set of proteins. The two centres are displaced relative to one another by 20 A in the model structure, in good agreement with the experimental value of 25 A found by neutron scattering.     

Functional heterogeneity of the 30S ribosomal subunit of Escherichia coli. II. Effect of S21 on initiation

Summary Native 30S ribosomal subunits fromEscherichia coli are deficient in fractional protein S21, which is present on the monosome and polysome-derived 30S subunits. The presence of S21 prevents the binding of Fmet-tRNA if and only if 50S subunits are present. In contrast, proteins S2, S3 and S14 stimulate the binding of Fmet-tRNA. These results have been used to rationalize other data concerning the mechanism of Fmet-tRNA binding by ribosomes. In addition, the present data indicate that the 30S ribosomal subunits are heterogeneousin vivo as well asin vitro.Dedicated to Professor H. Veldstra on the occasion of his retirement from the chair of biochemistry of the University of Leiden.     

Functional heterogeneity of the 30S ribosomal subunit of E. coli

Summary When 30S ribosomal subunits from E. coli are incubated with poly U, two separable components are recovered by zonal centrifugation of the incubation mixture. The faster sedimenting component is an aggregate of 30S subunits and poly U, while the slower one corresponds to the 30S ribosomal subunit. One ribosomal protein, protein 30S-1 is predominantly present in the faster sedimenting aggregate. The amount of poly U-30S subunit complex formed in the incubation mixture is limited by the amount of protein 30S-1 present. Consequently the number of ribosomal binding sites available for Phe-tRNA is limited in a similar fashion by the presence of protein 30S-1. When 30S ribosomal subunits are reconstituted in the absence of protein 30S-1, very little poly U or Phe-tRNA binding capacity is manifest under our assay conditions. We conclude that protein 30S-1 is required for maximum capacity of ribosomes to bind mRNA. Since this protein is present only on a fraction of the ribosome at any one time, it must exchange from one ribosome to another during protein synthesis.Abbreviations Poly U (polyuridylic acid) - t-RNA (transfer ribonucleic acid) - mRNA (messenger ribonucleic acid) - Phe (phenylanine) - A₂₆₀ unit (unit of material which gives an optical density of 1.0 at 260 nm in a one centimeter optical path)