Abstract
Yeast mitochondria contain a minimalist threonyl-tRNA synthetase (ThrRS) composed only of the catalytic core and tRNA binding domain but lacking the entire editing domain. Besides the usual tRNAThr2, some budding yeasts, such as Saccharomyces cerevisiae, also contain a non-canonical tRNAThr1 with an enlarged 8-nucleotide anticodon loop, reprograming the usual leucine CUN codons to threonine. This raises interesting questions about the aminoacylation fidelity of such ThrRSs and the possible contribution of the two tRNAThrs during editing. Here, we found that, despite the absence of the editing domain, S. cerevisiae mitochondrial ThrRS (ScmtThrRS) harbors a tRNA-dependent pre-transfer editing activity. Remarkably, only the usual tRNAThr2 stimulated pre-transfer editing, thus, establishing the first example of a synthetase exhibiting tRNA-isoacceptor specificity during pre-transfer editing. We also showed that the failure of tRNAThr1 to stimulate tRNA-dependent pre-transfer editing was due to the lack of an editing domain. Using assays of the complementation of a ScmtThrRS gene knockout strain, we showed that the catalytic core and tRNA binding domain of ScmtThrRS co-evolved to recognize the unusual tRNAThr1. In combination, the results provide insights into the tRNA-dependent editing process and suggest that tRNA-dependent pre-transfer editing takes place in the aminoacylation catalytic core.
Highlights
Accurate transfer of genetic information is of critical significance for cellular function and maintenance
We showed that ScmtThrRS exhibits a tRNA-dependent pre-transfer editing activity that is specific for the tRNA Thr2 isoacceptor, whereas tRNAThr1 was unable to stimulate such activity
We initially investigated whether E. coli threonyltRNA synthetase (ThrRS) (EcThrRS) and S. cerevisiae cytoplasmic ThrRS (SccytThrRS) were able to recognize the unusual tRNAThr1 and whether ScmtThrRS could aminoacylate other canonical forms of tRNAThr, such as S. cerevisiae cytoplasmic tRNAThr(AGU) (SctRNAThr)
Summary
Accurate transfer of genetic information is of critical significance for cellular function and maintenance. Protein synthesis is initiated by an ancient group of enzymes, the aminoacyl-tRNA synthetases (aaRSs) containing 20 members in the majority of living species [2,3,4] These enzymes catalyze the ligation of a specific amino acid to their specific tRNA-isoacceptors. The first step involves adenosine triphosphate (ATP)-dependent amino acid activation in which an intermediate aminoacyl-(adenosine monophosphate (AMP)) is generated with the release of pyrophosphate. This is followed by the transfer of the activated amino acid moiety from the aminoacyl-AMP to the tRNA [2]
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