Specific ribonucleoprotein fragments from 40-S ribosomal subunits.

Well-defined ribonucleoprotein fragments, resulting from the action of endogenous nuclease on 40-S subunits, were able to be separated when using high concentrations of LiCl. The ribonucleoproteins obtained sedimented at 12, 17 S, 23 S and 30 S and contained 8 S, 12 S and 17 S RNA, respectively, associated with a few proteins. The proteins extracted from the fragments were [3H] labeled by reductive methylation and their molar proportion was determined. The smallest fragment (12, 17 S) contained only three proteins, S8, S9 and S24. The 23-S and 30-S materials contained some proteins in common, S15, S19, S22, S25; S16 was found mainly in 30 S. Two proteins, S26 and "protein y" were found mainly in 23 S material. Thus, these results can give information on the relative location of certain proteins in the 40-S subunits.     

Characterisation of RNA fragments obtained by mild nuclease digestion of 30-S ribosomal subunits from Escherichia coli.

When Escherichia coli 30-S ribosomal subunits are hydrolysed under mild conditions, two ribonucleoprotein fragments of unequal size are produced. Knowledge of the RNA sequences contained in these hydrolysis products was required for the experiments described in the preceding paper, and the RNA sub-fragments have therefore been examined by oligonucleotide analysis. Two well-defined small fragments of free RNA, produced concomitantly with the ribonucleoprotein fragments, were also analysed. The larger ribonucleoprotein fragment, containing predominantly proteins S4, S5, S8, S15, S16 (17) and S20, contains a complex mixture of RNA sub-fragments varying from about 100 to 800 nucleotides in length. All these fragments arose from the 5'-terminal 900 nucleotides of 16-S RNA, corresponding to the well-known 12-S fragment. No long-range interactions could be detected within this RNA region in these experiments. The RNA from the smaller ribonucleoprotein fragment (containing proteins S7, S9 S10, S14 and S19) has been described in detail previously, and consists of about 450 nucleotides near the 3' end of the 16-S RNA, but lacking the 3'-terminal 150 nucleotides. The two small free RNA fragments (above) partly account for these missing 150 nucleotides; both fragments arose from section A of the 16-S RNA, but section J (the 3'-terminal 50 nucleotides) was not found. This result suggests that the 3' region of 16-S RNA is not involved in stable interactions with protein.     

The effect of modification of cytosines in Escherichia coli 16-S rRNA on reconstitution and function of 30-S ribosomes.

O-Methylhydroxylamine (methoxyamine) was used for selective modification of cytosine residues in Escherichia coli 16-S rRNA. It was shown that cytosines accessible for methoxyamination are randomly distributed along the 16-S rRNA chain. Preparations of methoxyaminated 16-S rRNA, containing 2--130 modified cytosines/chain, still retained the ability to bind 30-S proteins, but the physical assembly of reconstituted particles was incorrect. The protein compositions of the reconstituted and native particles did not differ qualitatively from each other. However, the amount of protein in reconstituted particles decreased with an increasing number of methoxyaminated cytosines in 16-S rRNA. The particles obtained sedimented slower than native 30-S subunits, lost their ability to associate with 50-S ribosomes and to bind native phage f2 RNA. In contrast, modification of 16-S rRNA did not affect binding of poly(U) by reconstituted particles.     

RNA sequences in ribonucleoprotein fragments of the complex formed from ribosomal 23-S RNA and ribosomal protein L24 of Escherichia coli.

Upon digestion of the complex formed from the 23-S ribosomal RNA and the 50-S ribosomal protein L24 of Escherichia coli, two fragments resistant to ribonuclease were recovered; these fragments contained RNA sections belonging to the 480 nucleotides at the 5' end of 23-S RNA. By determining the sequence of 70% of this latter region we were able to localise the sections which, in the presence of the protein, are resistant to ribonuclease. Our results suggest that the region encompassing the 480 nucleotides starting at the 9th nucleotide from the 5' end of 23-S RNA has a compact tertiary structure, which is stabilised by protein L24.     

Chemical inactivation of Escherichia coli 30-S ribosomes by iodination. Identification of proteins involved in tRNA binding.

30-S ribosomal subunits are inactivated by iodination for both enzymic fMet-tRNA and non-enzymic Phe-tRNA binding activities. This inactivation is due to modification of the protein moiety of the ribosome. Reconstitutions were performed with 16-S RNA and mixtures of total protein isolated from modified subunits and purified proteins isolated from unmodified subunits. This allowed identification of the individual proteins which restore tRNA binding activity. S3, S14 and S19 were identified as proteins involved in fMet-tRNA binding. S1, S2, S3, S14 and S19 were identified as proteins involved in Phe-tRNA binding. Modified particles shown normal sedimentation constants and complete protein compositions both before and after reconstitution. This suggests that the loss of activity is due to modification of one or more of the actual binding sites located on the 30-S subunit and that restoration of activity is due to structural correction at this site rather than to correction of an assembly defect.     

500-MHz 1H-NMR studies of ribosomal proteins isolated from 70-S ribosomes of Escherichia coli

A method for the large-scale isolation of ribosomal proteins is described avoiding pre-separation of 30-S and 50-S subunits. Five proteins isolated in this way were studied with high-resolution 1H NMR at 500 MHz. These are S21, L18, L25, L30 and L33. The results show that L18, L25 and L30 exhibit tertiary structure in solution and indications for secondary structure in S21 are found. Protein L33 appears to be a random coil. Several resonances in the 1H NMR spectra are assigned to particular protons of amino acid residues, e.g. the aromatic ring protons of tyrosines and histidines, and epsilon-protons of lysines.     

A 30 S precursor of 30 S ribosomes in a mutant of Escherichia coli.

Escherichia coli 15-28, a mutant with a defect in ribosome metabolism, accumulates a ribonucleoprotein particle that is indistinguishable from 30S subunits by sedimentation but contains the precursor form of 16S RNA. This particle is probably a precursor of 30 S ribosomes.