THE RIBOSOMAL TRANSFER RNA: IDENTIFICATION, ISOLATION, LOCATION AND PROPERTIES

A search for O-polypeptidyl-ribonucleic acids in rabbit-reticulocyte ribosomes by electrophoresis in phenol-acetic acid-water systems

1. When solutions of ;soluble' or transfer RNA (s-RNA) and of cytochrome c in phenol-acetic acid-water were mixed, intractable coacervates were formed. The addition to the solutions of various strong electrolytes prevented coacervation and allowed electrophoretic separation on filter paper. Protein migrates cationically, leaving RNA at or near the origin. The separation is aided by adsorption of RNA to the paper. Special arrangements were necessary to prevent contamination of the paper by ultraviolet-absorbing electrode-reaction products. 2. Binding of alkali-metal cations to RNA and some other associations were observed in such solvent systems. Possible effects of ionic association on mobilities are discussed. 3. Rabbit-reticulocyte ribosomes were subjected to electrophoresis as above, after their nascent-protein moiety had been labelled with [(14)C]valine in the intact cell. Most of the radioactivity migrated with the ribosomal protein; such protein as remained near the origin with the RNA had valine of lower specific radioactivity. 4. Molecular-sieve chromatography in phenol-acetic acid-water indicated that the nascent-protein moiety was not of markedly lower molecular weight than the average for the ribosomal proteins. 5. These results are very tentatively taken to mean that the nascent-protein moiety of ribosomes so prepared is not O-polypeptidyl-s-RNA. It is postulated that, in the course of adding each amino acid residue, the growing polypeptide chain is transferred from ester linkage with s-RNA to linkage with ribosomal protein through its carboxyl group, perhaps by ester linkage to an alcoholic group. The two types of intermediate, O-polypeptidyl-s-RNA and polypeptidyl-protein, would be found in different proportions, depending on the isolation procedure used. Some implications and possible tests of this hypothesis are discussed.

The sedimentation behaviour of ribonuclease-active and -inactive ribosomes from bacteria

1. The ;30s' and ;50s' ribosomes from ribonuclease-active (Escherichia coli B) and -inactive (Pseudomonas fluorescens and Escherichia coli MRE600) bacteria have been studied in the ultracentrifuge. Charge anomalies were largely overcome by using sodium chloride-magnesium chloride solution, I 0.16, made 0-50mm with respect to Mg(2+). 2. Differentiation of enzymic and physical breakdown at Mg(2+) concentrations less than 5mm was made by comparing the properties of E. coli B and P. fluorescens ribosomes. 3. Ribonuclease-active ribosomes alone showed a transformation of ;50s' into 40-43s components. This was combined with the release of a small amount of ;5s' material which may be covalently bound soluble RNA. Other transformations of the ;50s' into 34-37s components were observed in both ribonuclease-active and -inactive ribosomes at 1.0-2.5mm-Mg(2+), and also with E. coli MRE600 when EDTA (0.2mm) was added to a solution in 0.16m-sodium chloride. 4. Degradation of ribonuclease-active E. coli B ribosomes at Mg(2+) concentration 0.25mm or less was coincident with the formation of 16s and 21s ribonucleoprotein in P. fluorescens, and this suggested that complete dissociation of RNA from protein was not an essential prelude to breakdown of the RNA by the enzyme. 5. As high Cs(+)/Mg(2+) ratios cause ribosomal degradation great care is necessary in the interpretation of equilibrium-density-gradient experiments in which high concentrations of caesium chloride or similar salts are used. 6. The importance of the RNA moiety in understanding the response of ribosomes to their ionic environment is discussed.