Author
Listed:
- Laura K. White
(University of Colorado School of Medicine)
- Aleksandar Radakovic
(Harvard Medical School
Howard Hughes Medical Institute, The University of Chicago)
- Marcin P. Sajek
(University of Colorado School of Medicine
Institute of Human Genetics)
- Kezia Dobson
(University of Colorado School of Medicine)
- Kent A. Riemondy
(University of Colorado School of Medicine)
- Samantha Pozo
(University of Colorado School of Medicine)
- Jack W. Szostak
(Howard Hughes Medical Institute, The University of Chicago)
- Jay R. Hesselberth
(University of Colorado School of Medicine)
Abstract
The intricate landscape of tRNA modification presents persistent analytical challenges, which have impeded efforts to simultaneously resolve sequence, modification, and aminoacylation state at the level of individual tRNAs. To address these challenges, we introduce “aa-tRNA-seq”, an integrated method that uses chemical ligation to sandwich the amino acid of a charged tRNA in between the body of the tRNA and an adaptor oligonucleotide, followed by high throughput nanopore sequencing. Our approach reveals the identity of the amino acids attached to all tRNAs in a cellular sample, at the single molecule level. We describe machine learning models that enable the accurate identification of amino acid identities based on the unique signal distortions generated by the interactions between the amino acid in the RNA backbone and the nanopore motor protein and reader head. We apply aa-tRNA-seq to characterize the impact of the loss of specific tRNA modification enzymes, confirming the hypomodification-associated instability of specific tRNAs, and identifying additional candidate targets of modification. Our studies lay the groundwork for understanding the efficiency and fidelity of tRNA aminoacylation as a function of tRNA sequence, modification, and environmental conditions.
Suggested Citation
Laura K. White & Aleksandar Radakovic & Marcin P. Sajek & Kezia Dobson & Kent A. Riemondy & Samantha Pozo & Jack W. Szostak & Jay R. Hesselberth, 2025.
"Nanopore sequencing of intact aminoacylated tRNAs,"
Nature Communications, Nature, vol. 16(1), pages 1-15, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-62545-9
DOI: 10.1038/s41467-025-62545-9
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