tRNA‐dependent amino acid discrimination by yeast seryl‐tRNA synthetase

Abstract

The ability of aminoacyl-tRNA synthetases to distinguish between similar amino acids is crucial for accurate translation of the genetic code. Saccharomyces cerevisiae seryl-tRNA synthetase (SerRS) employs tRNA-dependent recognition of its cognate amino acid serine [Lenhard, B., Filipic, S., Landeka, I., Skrtic, I., Söll, D. & Weygand-Durasevic, I. (1997) J. Biol. Chem.272, 1136–1141]. Here we show that dimeric SerRS enzyme complexed with one molecule of tRNA^Ser is more specific and more efficient in catalyzing seryl-adenylate formation than the apoenzyme alone. Sequence-specific tRNA–protein interactions enhance discrimination of the amino acid substrate by yeast SerRS and diminish the misactivation of the structurally similar noncognate threonine. This may proceed via a tRNA-induced conformational change in the enzyme's active site. The 3′-terminal adenosine of tRNA^Ser is not important in effecting the rearrangement of the serine binding site. Our results do not provide an indication for a readjustment of ATP binding in a tRNA-assisted manner. The stoichiometric analyses of the complexes between the enzyme and tRNA^Ser revealed that two cognate tRNA molecules can be bound to dimeric SerRS, however, with very different affinities.