Mitochondrial tRNA editing. Mitochondrial Function and Biogenesis. Berlin: Springer Berlin Heidelberg; 2004. pp. 81-96. [DOI: 10.1007/b95713]

Aberrant Mitochondrial tRNA Genes Appear Frequently in Animal Evolution

Mitochondrial tRNAs have acquired a diverse portfolio of aberrant structures throughout metazoan evolution. With the availability of more than 12,500 mitogenome sequences, it is essential to compile a comprehensive overview of the pattern changes with regard to mitochondrial tRNA repertoire and structural variations. This, of course, requires reanalysis of the sequence data of more than 250,000 mitochondrial tRNAs with a uniform workflow. Here, we report our results on the complete reannotation of all mitogenomes available in the RefSeq database by September 2022 using mitos2. Based on the individual cases of mitochondrial tRNA variants reported throughout the literature, our data pinpoint the respective hotspots of change, i.e. Acanthocephala (Lophotrochozoa), Nematoda, Acariformes, and Araneae (Arthropoda). Less dramatic deviations of mitochondrial tRNAs from the norm are observed throughout many other clades. Loss of arms in animal mitochondrial tRNA clearly is a phenomenon that occurred independently many times, not limited to a small number of specific clades. The summary data here provide a starting point for systematic investigations into the detailed evolutionary processes of structural reduction and loss of mitochondrial tRNAs as well as a resource for further improvements of annotation workflows for mitochondrial tRNA annotation.

The TRAMP complex shows tRNA editing activity in S. cerevisiae

Transfer RNA (tRNA) editing is a widespread processing phenomenon that alters the sequence of primary transcripts by base substitutions as well as nucleotide deletions and insertions at internal or terminal transcript positions. In the corresponding tRNAs, these events are an important prerequisite for the generation of functional transcripts. Although many editing events are well characterized at the reaction level, it is unclear in most cases from which ancestral activities the modern editing enzymes evolved. Here, we show that in Saccharomyces cerevisiae, the noncanonical poly(A) polymerase Trf4p in the TRAMP complex can be recruited for such an editing reaction at an introduced tRNA transcript. As a distributive polymerase involved in RNA surveillance and quality control, it has a broad substrate spectrum and binds only transiently to the transcripts, limiting the number of added nucleotides at the editing position. These features exactly meet the criteria for an ancestral enzyme of a modern editing activity. Accordingly, our observations are a strong experimental support for the hypothesis that enzymatic promiscuity serves as an evolutionary starting point for the emergence of new functions and activities.