Proofreading Step Research Articles

Comparison of the misreading induced by streptomycin and neomycin

In a poly(U)-programmed translation system, neomycin stimulates the misincorporation of tyrosine and of serine which, according to Thompson and Stone (Thompson, R.C. and Stone, P.J. (1977) Proc. Natl. Acad. Sci. USA. 74, 198–202), are normally rejected at an initial discrimination step during the binding of charged tRNAs to the ribosome. In contrast, streptomycin favors the misincorporation of isoleucine which is normally rejected at a subsequent GTP-dependent discrimination step, the so-called proofreading step. The labeling of the ribosome with N- ethylmaleimide mimics the effect of streptomycin in that it stimulates the misincorporation of isoleucine but not of tyrosine or serine. This effect is correlated with the labeling of protein S18 but not with that of protein S1. These observations indicate that the sulfhydryl group of protein S18 is located within a ribosomal domain involved in the proofreading control of tRNA selection. Taking into account our previous results that streptomycin and neomycin perturb ribosomal areas around the sulfhydryl groups of proteins S18 and S1, respectively, we suggest that these antibiotics induce misreading by different mechanisms which are linked to such perturbations.

Proofreading of the codon-anticodon interaction on ribosomes.

The fidelity of protein synthesis is substantially greater than the specificity of codon-anticodon recognition that would be expected from the known energetics of base-pairing in solution. To test the suggestion that the specificity of recognition may be increased by "kinetic proofreading" associated with GTP hydrolysis [J. J. Hopfield (1974) Proc. Natl. Acad. Sci. USA 71, 4135-4139], we have studied the interaction of ternary complexes of polypeptide elongation factor Tu, aminoacyl-tRNA, and GTP with poly(U)-programed ribosomes. With most noncognate ternary complexes, including two that pair correctly with the 5' and 3' bases of UUU, rejection occurred without GTP hydrolysis, presumably by the reverse of the initial binding reaction. However, with complexes containing Leu- or Ile-tRNAs, which may pair correctly with the 3' and middle bases, GTP hydrolysis was stimulated though the aa-tRNA was not retained on the ribosome. These results demonstrate the existence of a GTP-dependent proofreading step in aminoacyl-tRNA recognition on ribosomes. They also suggest that the 5' base of the codon is more prone than the middle base to errors that can be corrected by proofreading.