tRNA Modification Profiles and Codon-Decoding Strategies in Methanocaldococcus jannaschii.

tRNAs play a critical role in mRNA decoding, and posttranscriptional modifications within tRNAs drive decoding efficiency and accuracy. The types and positions of tRNA modifications in model bacteria have been extensively studied, and tRNA modifications in a few eukaryotic organisms have also been characterized and localized to particular tRNA sequences. However, far less is known regarding tRNA modifications in archaea. While the identities of modifications have been determined for multiple archaeal organisms, is the only organism for which modifications have been extensively localized to specific tRNA sequences. To improve our understanding of archaeal tRNA modification patterns and codon-decoding strategies, we have used liquid chromatography and tandem mass spectrometry to characterize and then map posttranscriptional modifications on 34 of the 35 unique tRNA sequences of A new posttranscriptionally modified nucleoside, 5-cyanomethyl-2-thiouridine (cnmsU), was discovered and localized to position 34. Moreover, data consistent with wyosine pathway modifications were obtained beyond the canonical tRNA as is typical for eukaryotes. The high-quality mapping of tRNA anticodon loops enriches our understanding of archaeal tRNA modification profiles and decoding strategies. While many posttranscriptional modifications in tRNAs are also found in bacteria and eukaryotes, several that are unique to archaea were identified. By RNA modification mapping, the modification profiles of tRNA anticodon loops were characterized, allowing a comparative analysis with modification profiles as well as a general comparison with bacterial and eukaryotic decoding strategies. This general comparison reveals that , like , follows codon-decoding strategies similar to those used by bacteria, although position 37 appears to be modified to a greater extent than seen in .