Exploiting nanopore sequencing advances for tRNA sequencing of human cancer models

Adva Kochavi; Arno Velds; Maya Suzuki; Shinichiro Akichika; Tsutomu Suzuki; Roderick L. Beijersbergen; Reuven Agami

doi:10.1093/narcan/zcaf044

Exploiting nanopore sequencing advances for tRNA sequencing of human cancer models

Adva Kochavi
, Arno Velds
, Maya Suzuki
, Shinichiro Akichika
, Tsutomu Suzuki
, Roderick L. Beijersbergen
, Reuven Agami^*

^*Corresponding author for this work

Molecular Genetics

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Transfer RNAs (tRNAs) are essential regulators of protein synthesis, and dysregulation of their abundance and modification status is involved in many human diseases including cancer. Despite the rapid development of novel tRNA sequencing approaches, due to tRNAs’ stable secondary structure and abundant modification sites, the human tRNA landscape has remained mostly unexplored. Here, we evaluated the new RNA004 chemistry of Oxford Nanopore Technologies, that is integrated with updated Dorado base-caller models, for tRNA quantification and modification annotation in human cancer models. We demonstrated that this technology identifies variations in tRNA expression across cancer cell lines and in response to external stress conditions, with highly reproducible results. We also show that analysis of base-calling error rate can indicate the presence of known modifications, including the cancer-associated tRNA^Phe-Wybutosine modification. Furthermore, implementing the updated Dorado modification-calling feature, we showed the potential of RNA004 tRNA-seq in predicting common tRNA modifications. We also pinpointed possible limitations and challenges associated with both modification calling methods. Overall, RNA004 tRNA-seq can potentially enhance our understanding of the human tRNAome by simultaneously analyzing both tRNA abundance and modifications.

Original language	English
Article number	zcaf044
Journal	NAR Cancer
Volume	7
Issue number	4
DOIs	https://doi.org/10.1093/narcan/zcaf044
Publication status	Published - 1 Dec 2025

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© The Author(s) 2025. Published by Oxford University Press.

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title = "Exploiting nanopore sequencing advances for tRNA sequencing of human cancer models",

abstract = "Transfer RNAs (tRNAs) are essential regulators of protein synthesis, and dysregulation of their abundance and modification status is involved in many human diseases including cancer. Despite the rapid development of novel tRNA sequencing approaches, due to tRNAs{\textquoteright} stable secondary structure and abundant modification sites, the human tRNA landscape has remained mostly unexplored. Here, we evaluated the new RNA004 chemistry of Oxford Nanopore Technologies, that is integrated with updated Dorado base-caller models, for tRNA quantification and modification annotation in human cancer models. We demonstrated that this technology identifies variations in tRNA expression across cancer cell lines and in response to external stress conditions, with highly reproducible results. We also show that analysis of base-calling error rate can indicate the presence of known modifications, including the cancer-associated tRNAPhe-Wybutosine modification. Furthermore, implementing the updated Dorado modification-calling feature, we showed the potential of RNA004 tRNA-seq in predicting common tRNA modifications. We also pinpointed possible limitations and challenges associated with both modification calling methods. Overall, RNA004 tRNA-seq can potentially enhance our understanding of the human tRNAome by simultaneously analyzing both tRNA abundance and modifications.",

author = "Adva Kochavi and Arno Velds and Maya Suzuki and Shinichiro Akichika and Tsutomu Suzuki and Beijersbergen, \{Roderick L.\} and Reuven Agami",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025. Published by Oxford University Press.",

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T1 - Exploiting nanopore sequencing advances for tRNA sequencing of human cancer models

AU - Kochavi, Adva

AU - Velds, Arno

AU - Suzuki, Maya

AU - Akichika, Shinichiro

AU - Suzuki, Tsutomu

AU - Beijersbergen, Roderick L.

AU - Agami, Reuven

PY - 2025/12/1

Y1 - 2025/12/1

N2 - Transfer RNAs (tRNAs) are essential regulators of protein synthesis, and dysregulation of their abundance and modification status is involved in many human diseases including cancer. Despite the rapid development of novel tRNA sequencing approaches, due to tRNAs’ stable secondary structure and abundant modification sites, the human tRNA landscape has remained mostly unexplored. Here, we evaluated the new RNA004 chemistry of Oxford Nanopore Technologies, that is integrated with updated Dorado base-caller models, for tRNA quantification and modification annotation in human cancer models. We demonstrated that this technology identifies variations in tRNA expression across cancer cell lines and in response to external stress conditions, with highly reproducible results. We also show that analysis of base-calling error rate can indicate the presence of known modifications, including the cancer-associated tRNAPhe-Wybutosine modification. Furthermore, implementing the updated Dorado modification-calling feature, we showed the potential of RNA004 tRNA-seq in predicting common tRNA modifications. We also pinpointed possible limitations and challenges associated with both modification calling methods. Overall, RNA004 tRNA-seq can potentially enhance our understanding of the human tRNAome by simultaneously analyzing both tRNA abundance and modifications.

AB - Transfer RNAs (tRNAs) are essential regulators of protein synthesis, and dysregulation of their abundance and modification status is involved in many human diseases including cancer. Despite the rapid development of novel tRNA sequencing approaches, due to tRNAs’ stable secondary structure and abundant modification sites, the human tRNA landscape has remained mostly unexplored. Here, we evaluated the new RNA004 chemistry of Oxford Nanopore Technologies, that is integrated with updated Dorado base-caller models, for tRNA quantification and modification annotation in human cancer models. We demonstrated that this technology identifies variations in tRNA expression across cancer cell lines and in response to external stress conditions, with highly reproducible results. We also show that analysis of base-calling error rate can indicate the presence of known modifications, including the cancer-associated tRNAPhe-Wybutosine modification. Furthermore, implementing the updated Dorado modification-calling feature, we showed the potential of RNA004 tRNA-seq in predicting common tRNA modifications. We also pinpointed possible limitations and challenges associated with both modification calling methods. Overall, RNA004 tRNA-seq can potentially enhance our understanding of the human tRNAome by simultaneously analyzing both tRNA abundance and modifications.

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DO - 10.1093/narcan/zcaf044

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JO - NAR Cancer

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M1 - zcaf044

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Exploiting nanopore sequencing advances for tRNA sequencing of human cancer models

Abstract

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