Protein synthesis involves two methionine-isoaccepting tRNAs, an initiator and an elongator. In eubacteria, mitochondria, and chloroplasts, the addition of a formyl group gives its full functional identity to initiator MettRNA Met . In Escherichia coli, it has been shown that the specific action of methionyl-tRNA transformylase on Met-tRNA f Met mainly involves a set of nucleotides in the acceptor stem, particularly a C 1 A 72 mismatch. In animal mitochondria, only one tRNA Met species has yet been described. It is admitted that this species can engage itself either in initiation or elongation of translation, depending on the presence or absence of a formyl group. In the present study, we searched for the identity elements of tRNA Met that govern its formylation by bovine mitochondrial transformylase. The main conclusion is that the mitochondrial formylase preferentially recognizes the methionyl moiety of its tRNA substrate. Moreover, the relatively small importance of the tRNA acceptor stem in the recognition process accounts for the protection against formylation of the mitochondrial tRNAs that share with tRNA Met an A 1 U 72 motif.
Initiation of protein synthesis in bacteria, mitochondria, and chloroplasts involves a formylated methionyl-tRNA species. Formylation of this tRNA is catalyzed by a methionyl-tRNA(f)(Met) formyltransferase (formylase). Upon inactivation of the gene encoding formylase, the growth rate of Escherichia coli is severely decreased. This behavior underlines the importance of formylation to give tRNA(Met) an initiator identity. Surprisingly, however, recent data [Li, Y., Holmes, W. B., Appling, D. R., and RajBhandary, U. L. (2000) J. Bacteriol. 182, 2886-2892] showed that the respiratory growth of Saccharomyces cerevisiaewas not sensitive to deprivation of the mitochondrial formylase. In the present study, we report conditions of temperature or of growth medium composition in which inactivation of the formylase gene indeed impairs the growth of a S. cerevisiae haploid strain. Therefore, some selective advantage can eventually be associated to the existence of a formylating activity in the fungal mitochondrion under severe growth conditions. Finally, the specificity toward tRNA of S. cerevisiae mitochondrial formylase was studied using E. coli initiator tRNA and mutants derived from it. Like its bacterial counterpart, this formylase recognizes nucleotidic features in the acceptor stem of mitochondrial initiator tRNA. This behavior markedly distinguishes the mitochondrial formylase of yeast from that of animals. Indeed, it was shown that bovine mitochondrial formylase mainly recognizes the side chain of the esterified methionine plus a purine-pyrimidine base pair in the D-stem of tRNA [Takeuchi, N., Vial, L., Panvert, M., Schmitt, E., Watanabe, K., Mechulam, Y., and Blanquet, S. (2001) J. Biol. Chem. 276, 20064-20068]. Distinct tRNA recognition mechanisms adopted by the formylases of prokaryotic, fungal, or mammalian origins are likely to reflect coevolution of these enzymes with their tRNA substrate. Each mechanism appears well suited to an efficient selection of the substrate within the pool of all tRNAs.
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