Direct detection of 8-oxo-dG using nanopore sequencing

Marc Pagès-Gallego; Daan M.K. van Soest; Nicolle J.M. Besselink; Roy Straver; Janneke P. Keijer; Carlo Vermeulen; Alessio Marcozzi; Markus J. van Roosmalen; Ruben van Boxtel; Boudewijn M.T. Burgering; Tobias B. Dansen; Jeroen de Ridder

doi:10.1038/s41467-025-60391-3

Direct detection of 8-oxo-dG using nanopore sequencing

Marc Pagès-Gallego, Daan M.K. van Soest, Nicolle J.M. Besselink, Roy Straver, Janneke P. Keijer, Carlo Vermeulen, Alessio Marcozzi, Markus J. van Roosmalen, Ruben van Boxtel, Boudewijn M.T. Burgering^*, Tobias B. Dansen^*, Jeroen de Ridder^*

^*Corresponding author for this work

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

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Abstract

Genomic DNA is under constant oxidative damage, with 8-oxo-7,8-dihydro-2’-deoxyguanosine (8-oxo-dG) being the prominent lesion linked to mutagenesis, epigenetics, and gene regulation. Existing methods to detect 8-oxo-dG rely on indirect approaches, while nanopore sequencing enables direct detection of base modifications. A model for 8-oxo-dG detection is currently missing due to the lack of training data. Here, we develop a strategy using synthetic oligos to generate long, 8-oxo-dG context-variable DNA molecules for deep learning and nanopore sequencing. Our training approach addresses the rarity of 8-oxo-dG relative to guanine, enabling specific detection. Applied to a tissue culture model of oxidative damage, our method reveals uneven genomic 8-oxo-dG distribution, dissimilar context pattern to C>A mutations, and local 5-mC depletion. This dual measurement of 5-mC and 8-oxo-dG at single-molecule resolution uncovers new insights into their interplay. Our approach also provides a general framework for detecting other rare DNA modifications using synthetic DNA and nanopore sequencing.

Original language	English
Article number	5236
Number of pages	15
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-60391-3
Publication status	Published - 5 Jun 2025

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title = "Direct detection of 8-oxo-dG using nanopore sequencing",

abstract = "Genomic DNA is under constant oxidative damage, with 8-oxo-7,8-dihydro-2{\textquoteright}-deoxyguanosine (8-oxo-dG) being the prominent lesion linked to mutagenesis, epigenetics, and gene regulation. Existing methods to detect 8-oxo-dG rely on indirect approaches, while nanopore sequencing enables direct detection of base modifications. A model for 8-oxo-dG detection is currently missing due to the lack of training data. Here, we develop a strategy using synthetic oligos to generate long, 8-oxo-dG context-variable DNA molecules for deep learning and nanopore sequencing. Our training approach addresses the rarity of 8-oxo-dG relative to guanine, enabling specific detection. Applied to a tissue culture model of oxidative damage, our method reveals uneven genomic 8-oxo-dG distribution, dissimilar context pattern to C>A mutations, and local 5-mC depletion. This dual measurement of 5-mC and 8-oxo-dG at single-molecule resolution uncovers new insights into their interplay. Our approach also provides a general framework for detecting other rare DNA modifications using synthetic DNA and nanopore sequencing.",

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AU - Besselink, Nicolle J.M.

AU - Straver, Roy

AU - Keijer, Janneke P.

AU - Vermeulen, Carlo

AU - Marcozzi, Alessio

AU - van Roosmalen, Markus J.

AU - van Boxtel, Ruben

AU - Burgering, Boudewijn M.T.

AU - Dansen, Tobias B.

AU - de Ridder, Jeroen

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N2 - Genomic DNA is under constant oxidative damage, with 8-oxo-7,8-dihydro-2’-deoxyguanosine (8-oxo-dG) being the prominent lesion linked to mutagenesis, epigenetics, and gene regulation. Existing methods to detect 8-oxo-dG rely on indirect approaches, while nanopore sequencing enables direct detection of base modifications. A model for 8-oxo-dG detection is currently missing due to the lack of training data. Here, we develop a strategy using synthetic oligos to generate long, 8-oxo-dG context-variable DNA molecules for deep learning and nanopore sequencing. Our training approach addresses the rarity of 8-oxo-dG relative to guanine, enabling specific detection. Applied to a tissue culture model of oxidative damage, our method reveals uneven genomic 8-oxo-dG distribution, dissimilar context pattern to C>A mutations, and local 5-mC depletion. This dual measurement of 5-mC and 8-oxo-dG at single-molecule resolution uncovers new insights into their interplay. Our approach also provides a general framework for detecting other rare DNA modifications using synthetic DNA and nanopore sequencing.

AB - Genomic DNA is under constant oxidative damage, with 8-oxo-7,8-dihydro-2’-deoxyguanosine (8-oxo-dG) being the prominent lesion linked to mutagenesis, epigenetics, and gene regulation. Existing methods to detect 8-oxo-dG rely on indirect approaches, while nanopore sequencing enables direct detection of base modifications. A model for 8-oxo-dG detection is currently missing due to the lack of training data. Here, we develop a strategy using synthetic oligos to generate long, 8-oxo-dG context-variable DNA molecules for deep learning and nanopore sequencing. Our training approach addresses the rarity of 8-oxo-dG relative to guanine, enabling specific detection. Applied to a tissue culture model of oxidative damage, our method reveals uneven genomic 8-oxo-dG distribution, dissimilar context pattern to C>A mutations, and local 5-mC depletion. This dual measurement of 5-mC and 8-oxo-dG at single-molecule resolution uncovers new insights into their interplay. Our approach also provides a general framework for detecting other rare DNA modifications using synthetic DNA and nanopore sequencing.

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Direct detection of 8-oxo-dG using nanopore sequencing

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