Four minimal (119 - 145 residue) active site fragments of Escherichia coli Class II histidyl-tRNA synthetase were constructed, expressed as maltose-binding protein fusions, and assayed for histidine activation as fusion proteins and after TEV cleavage, using the 32PPi exchange assay. All contain conserved Motifs 1 and 2. Two contain an N-terminal extension of Motif 1 and two contain Motif 3. Five experimental results argue strongly for the authenticity of the observed catalytic activities: (i) active site titration experiments showing high (∼0.1–0.55) fractions of active molecules, (ii) release of cryptic activity by TEV cleavage of the fusion proteins, (iii) reduced activity associated with an active site mutation, (iv) quantitative attribution of increased catalytic activity to the intrinsic effects of Motif 3, the N-terminal extension and their synergistic effect, and (v) significantly altered Km values for both ATP and histidine substrates. It is therefore plausible that neither the insertion domain nor Motif 3 were essential for catalytic activity in the earliest Class II aminoacyl-tRNA synthetases. The mean rate enhancement of all four cleaved constructs is ∼109 times that of the estimated uncatalyzed rate. As observed for the tryptophanyl-tRNA synthetase (TrpRS) Urzyme, these fragments bind ATP tightly but have reduced affinity for cognate amino acids. These fragments thus likely represent Urzymes (Ur = primitive, original, earliest + enzyme) comparable in size and catalytic activity and coded by sequences proposed to be antisense to that coding the previously described Class I TrpRS Urzyme. Their catalytic activities provide metrics for experimental recapitulation of very early evolutionary events.
Retraction notice to “An active-site mutation enhances the catalytic activity of the yeast Cryptococcus humicola D-aspartate oxidase” Journal of Molecular Catalysis. B, Volume 61/3-4, December 2009, 1913