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. 2025 Oct 16;31(11):1619-1631.
doi: 10.1261/rna.080669.125.

A eukaryote without tRNA introns

Ambro van Hoof  1 Tokiko Furuta  2 Swathi Arur  2
Affiliations

A eukaryote without tRNA introns

Ambro van Hoof et al. RNA. .

Abstract

One of the striking characteristics of eukaryotic genomes is the presence of three types of introns: spliceosomal introns, tRNA introns, and a unique intron in the XBP1 mRNA. Exceptional eukaryotic genomes that lack spliceosomal or XBP1 introns have been described. However, tRNA introns and the tRNA endonuclease that is required for their splicing are thought to be universal in eukaryotes. The introns in three tRNAs are widely conserved across Metazoa: Tyr-GUA, Ile-UAU, and Leu-CAA. This study shows that some nematode species have lost the introns in Tyr-GUA and Ile-UAU tRNAs, and one species, Levipalatum texanum, completely lacks tRNA introns. The loss of the intron from Leu-CAA tRNA is accompanied by an unusual A-C mismatched base pair in the anticodon stem-loop and a triplication of a tRNA deaminase that could potentially restore base-pairing. These changes may be an adaptation to the loss of the intron. L. texanum also lacks the tRNA endonuclease, one of two enzymes required for tRNA splicing. The other key enzyme in tRNA splicing, tRNA ligase, is bifunctional and is also required for XBP1 mRNA splicing. L. texanum retains tRNA ligase and the XBP1 intron. This eukaryote without tRNA introns has the potential to be a valuable tool for disentangling the functions of tRNA splicing, XBP1 splicing, and tRNA modification enzymes and is the only animal known to have lost one of the three intron types.

Keywords: intron conservation; intron loss; tRNA intron; tRNA splicing.

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