Molecular dissection of a critical specificity determinant within the amino acid editing domain of leucyl-tRNA synthetase.

A highly conserved threonine residue marks the amino acid binding pocket within the editing active site of leucyl-tRNA synthetases (LeuRSs). It is essential to substrate specificity for the Escherichia coli enzyme in that it blocks the cognate leucine amino acid from binding in the hydrolytic editing active site. We combined mutagenesis and computational approaches to elucidate the molecular role of the critical side chain of this threonine residue. Removal of the terminal methyl group of the threonine side chain by replacement with serine yielded a mutant LeuRS that hydrolyzes Leu-tRNA(Leu). Substitution of valine for the conserved threonine conferred similar activities to the wild-type enzyme. However, an additional substitution within the editing active site suggested synergistic interactions with the conserved threonine site that significantly affected amino acid editing. On the basis of our combined biochemical and computational data, we propose that the threonine 252 side chain not only sterically hinders the cognate charged leucine from binding for hydrolysis but also plays a critical role in maintaining an active site geometry that is required for the fidelity of LeuRS.

Structural and mechanistic basis of pre- and posttransfer editing by leucyl-tRNA synthetase.

The aminoacyl-tRNA synthetases link tRNAs with their cognate amino acid. In some cases, their fidelity relies on hydrolytic editing that destroys incorrectly activated amino acids or mischarged tRNAs. We present structures of leucyl-tRNA synthetase complexed with analogs of the distinct pre- and posttransfer editing substrates. The editing active site binds the two different substrates using a single amino acid discriminatory pocket while preserving the same mode of adenine recognition. This suggests a similar mechanism of hydrolysis for both editing substrates that depends on a key, completely conserved aspartic acid, which interacts with the alpha-amino group of the noncognate amino acid and positions both substrates for hydrolysis. Our results demonstrate the economy by which a single active site accommodates two distinct substrates in a proofreading process critical to the fidelity of protein synthesis.

Rational design to block amino acid editing of a tRNA synthetase.

Investigations in chemical biology have focused on the synthesis of custom-designed proteins with site-specific incorporation of novel amino acids. Their success requires stable production of misacylated tRNAs. Utilization of aminoacyl-tRNA synthetases has been hindered because of enzyme molecular recognition mechanisms that ensure high fidelity of protein synthesis. Leucyl-tRNA synthetase naturally misaminoacylates chemically diverse standard and nonstandard amino acids, but contains a separate amino acid editing active site to hydrolyze incorrectly mischarged tRNAs. In this work, a rational mutagenesis design to block enzyme editing is described and involves substitution of bulky amino acids into the amino acid binding pocket of the hydrolytic active site. These engineered enzymes stably misacylated isoleucine to tRNALeu. The use of these mutant leucyl-tRNA synthetases has the potential to produce pools of mischarged tRNAs that are linked to nonstandard amino acids for in vitro translation. In addition, since many of the leucyl-tRNA synthetases do not interact with or rely upon the tRNA anticodon for identity, these enzymes may offer an excellent scaffold for the development of orthogonal tRNA synthetase/tRNA pairs that can potentially be used to customize protein synthesis.