Real-time analysis of the cancer genome and fragmentome from plasma and urine cell-free DNA using nanopore sequencing

Ymke van der Pol; Normastuti Adhini Tantyo; Nils Evander; Anouk E. Hentschel; Birgit M. M. Wever; Jip Ramaker; Sanne Bootsma; Marieke F. Fransen; Kristiaan J. Lenos; Louis Vermeulen; Famke L. Schneiders; Idris Bahce; Jakko A. Nieuwenhuijzen; Renske D. M. Steenbergen; D. Michiel Pegtel; Norbert Moldovan; Florent Mouliere

doi:https://doi.org/10.15252/emmm.202217282

Real-time analysis of the cancer genome and fragmentome from plasma and urine cell-free DNA using nanopore sequencing

Ymke van der Pol, Normastuti Adhini Tantyo, Nils Evander, Anouk E. Hentschel, Birgit M. M. Wever, Jip Ramaker, Sanne Bootsma, Marieke F. Fransen, Kristiaan J. Lenos, Louis Vermeulen, Famke L. Schneiders, Idris Bahce, Jakko A. Nieuwenhuijzen, Renske D. M. Steenbergen, D. Michiel Pegtel, Norbert Moldovan, Florent Mouliere

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

2 Citations (Scopus)

Abstract

Cell-free DNA (cfDNA) can be isolated and sequenced from blood and/or urine of cancer patients. Conventional short-read sequencing lacks deployability and speed and can be biased for short cfDNA fragments. Here, we demonstrate that with Oxford Nanopore Technologies (ONT) sequencing we can achieve delivery of genomic and fragmentomic data from liquid biopsies. Copy number aberrations and cfDNA fragmentation patterns can be determined in less than 24 h from sample collection. The tumor-derived cfDNA fraction calculated from plasma of lung cancer patients and urine of bladder cancer patients was highly correlated (R = 0.98) with the tumor fraction calculated from short-read sequencing of the same samples. cfDNA size profile, fragmentation patterns, fragment-end composition, and nucleosome profiling near transcription start sites in plasma and urine exhibited the typical cfDNA features. Additionally, a high proportion of long tumor-derived cfDNA fragments (> 300 bp) are recovered in plasma and urine using ONT sequencing. ONT sequencing is a cost-effective, fast, and deployable approach for obtaining genomic and fragmentomic results from liquid biopsies, allowing the analysis of previously understudied cfDNA populations.

Original language	English
Article number	e17282
Journal	EMBO molecular medicine
Volume	15
Issue number	12
Early online date	2023
DOIs	https://doi.org/10.15252/emmm.202217282
Publication status	Published - 7 Dec 2023

Keywords

cancer
cell-free DNA
fragmentomics
liquid biopsy
nanopore sequencing

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van der Pol, Y., Tantyo, N. A., Evander, N., Hentschel, A. E., Wever, B. M. M., Ramaker, J., Bootsma, S., Fransen, M. F., Lenos, K. J., Vermeulen, L., Schneiders, F. L., Bahce, I., Nieuwenhuijzen, J. A., Steenbergen, R. D. M., Pegtel, D. M., Moldovan, N., & Mouliere, F. (2023). Real-time analysis of the cancer genome and fragmentome from plasma and urine cell-free DNA using nanopore sequencing. EMBO molecular medicine, 15(12), Article e17282. https://doi.org/10.15252/emmm.202217282

@article{5eabb526a6634072948afaa86db5dadd,

title = "Real-time analysis of the cancer genome and fragmentome from plasma and urine cell-free DNA using nanopore sequencing",

abstract = "Cell-free DNA (cfDNA) can be isolated and sequenced from blood and/or urine of cancer patients. Conventional short-read sequencing lacks deployability and speed and can be biased for short cfDNA fragments. Here, we demonstrate that with Oxford Nanopore Technologies (ONT) sequencing we can achieve delivery of genomic and fragmentomic data from liquid biopsies. Copy number aberrations and cfDNA fragmentation patterns can be determined in less than 24 h from sample collection. The tumor-derived cfDNA fraction calculated from plasma of lung cancer patients and urine of bladder cancer patients was highly correlated (R = 0.98) with the tumor fraction calculated from short-read sequencing of the same samples. cfDNA size profile, fragmentation patterns, fragment-end composition, and nucleosome profiling near transcription start sites in plasma and urine exhibited the typical cfDNA features. Additionally, a high proportion of long tumor-derived cfDNA fragments (> 300 bp) are recovered in plasma and urine using ONT sequencing. ONT sequencing is a cost-effective, fast, and deployable approach for obtaining genomic and fragmentomic results from liquid biopsies, allowing the analysis of previously understudied cfDNA populations.",

keywords = "cancer, cell-free DNA, fragmentomics, liquid biopsy, nanopore sequencing",

author = "{van der Pol}, Ymke and Tantyo, {Normastuti Adhini} and Nils Evander and Hentschel, {Anouk E.} and Wever, {Birgit M. M.} and Jip Ramaker and Sanne Bootsma and Fransen, {Marieke F.} and Lenos, {Kristiaan J.} and Louis Vermeulen and Schneiders, {Famke L.} and Idris Bahce and Nieuwenhuijzen, {Jakko A.} and Steenbergen, {Renske D. M.} and Pegtel, {D. Michiel} and Norbert Moldovan and Florent Mouliere",

note = "Funding Information: The authors would like to thank Dr. Trang Vu, Ms. Birgit Wever, and Dr. Daoud Sie for their help and constructive discussions. The authors are thankful to the Amsterdam UMC Liquid Biopsy Center for the logistical support. YP and FM are funded by the Amsterdam UMC Liquid Biopsy Center, an initiative made possible through the Stichting Cancer Center Amsterdam. NM and FM are supported by a Dutch Cancer Fund (KWF‐12822). This work was carried out on the Dutch national e‐infrastructure with the support of SURF Cooperative. Funding Information: The authors would like to thank Dr. Trang Vu, Ms. Birgit Wever, and Dr. Daoud Sie for their help and constructive discussions. The authors are thankful to the Amsterdam UMC Liquid Biopsy Center for the logistical support. YP and FM are funded by the Amsterdam UMC Liquid Biopsy Center, an initiative made possible through the Stichting Cancer Center Amsterdam. NM and FM are supported by a Dutch Cancer Fund (KWF-12822). This work was carried out on the Dutch national e-infrastructure with the support of SURF Cooperative. Publisher Copyright: {\textcopyright} 2023 The Authors. Published under the terms of the CC BY 4.0 license.",

year = "2023",

month = dec,

day = "7",

doi = "https://doi.org/10.15252/emmm.202217282",

language = "English",

volume = "15",

journal = "EMBO molecular medicine",

issn = "1757-4676",

publisher = "Wiley-Blackwell",

number = "12",

}

van der Pol, Y, Tantyo, NA, Evander, N, Hentschel, AE, Wever, BMM, Ramaker, J, Bootsma, S , Fransen, MF , Lenos, KJ , Vermeulen, L , Schneiders, FL, Bahce, I, Nieuwenhuijzen, JA , Steenbergen, RDM , Pegtel, DM , Moldovan, N & Mouliere, F 2023, 'Real-time analysis of the cancer genome and fragmentome from plasma and urine cell-free DNA using nanopore sequencing', EMBO molecular medicine, vol. 15, no. 12, e17282. https://doi.org/10.15252/emmm.202217282

TY - JOUR

T1 - Real-time analysis of the cancer genome and fragmentome from plasma and urine cell-free DNA using nanopore sequencing

AU - van der Pol, Ymke

AU - Tantyo, Normastuti Adhini

AU - Evander, Nils

AU - Hentschel, Anouk E.

AU - Wever, Birgit M. M.

AU - Ramaker, Jip

AU - Bootsma, Sanne

AU - Fransen, Marieke F.

AU - Lenos, Kristiaan J.

AU - Vermeulen, Louis

AU - Schneiders, Famke L.

AU - Bahce, Idris

AU - Nieuwenhuijzen, Jakko A.

AU - Steenbergen, Renske D. M.

AU - Pegtel, D. Michiel

AU - Moldovan, Norbert

AU - Mouliere, Florent

N1 - Funding Information: The authors would like to thank Dr. Trang Vu, Ms. Birgit Wever, and Dr. Daoud Sie for their help and constructive discussions. The authors are thankful to the Amsterdam UMC Liquid Biopsy Center for the logistical support. YP and FM are funded by the Amsterdam UMC Liquid Biopsy Center, an initiative made possible through the Stichting Cancer Center Amsterdam. NM and FM are supported by a Dutch Cancer Fund (KWF‐12822). This work was carried out on the Dutch national e‐infrastructure with the support of SURF Cooperative. Funding Information: The authors would like to thank Dr. Trang Vu, Ms. Birgit Wever, and Dr. Daoud Sie for their help and constructive discussions. The authors are thankful to the Amsterdam UMC Liquid Biopsy Center for the logistical support. YP and FM are funded by the Amsterdam UMC Liquid Biopsy Center, an initiative made possible through the Stichting Cancer Center Amsterdam. NM and FM are supported by a Dutch Cancer Fund (KWF-12822). This work was carried out on the Dutch national e-infrastructure with the support of SURF Cooperative. Publisher Copyright: © 2023 The Authors. Published under the terms of the CC BY 4.0 license.

PY - 2023/12/7

Y1 - 2023/12/7

N2 - Cell-free DNA (cfDNA) can be isolated and sequenced from blood and/or urine of cancer patients. Conventional short-read sequencing lacks deployability and speed and can be biased for short cfDNA fragments. Here, we demonstrate that with Oxford Nanopore Technologies (ONT) sequencing we can achieve delivery of genomic and fragmentomic data from liquid biopsies. Copy number aberrations and cfDNA fragmentation patterns can be determined in less than 24 h from sample collection. The tumor-derived cfDNA fraction calculated from plasma of lung cancer patients and urine of bladder cancer patients was highly correlated (R = 0.98) with the tumor fraction calculated from short-read sequencing of the same samples. cfDNA size profile, fragmentation patterns, fragment-end composition, and nucleosome profiling near transcription start sites in plasma and urine exhibited the typical cfDNA features. Additionally, a high proportion of long tumor-derived cfDNA fragments (> 300 bp) are recovered in plasma and urine using ONT sequencing. ONT sequencing is a cost-effective, fast, and deployable approach for obtaining genomic and fragmentomic results from liquid biopsies, allowing the analysis of previously understudied cfDNA populations.

AB - Cell-free DNA (cfDNA) can be isolated and sequenced from blood and/or urine of cancer patients. Conventional short-read sequencing lacks deployability and speed and can be biased for short cfDNA fragments. Here, we demonstrate that with Oxford Nanopore Technologies (ONT) sequencing we can achieve delivery of genomic and fragmentomic data from liquid biopsies. Copy number aberrations and cfDNA fragmentation patterns can be determined in less than 24 h from sample collection. The tumor-derived cfDNA fraction calculated from plasma of lung cancer patients and urine of bladder cancer patients was highly correlated (R = 0.98) with the tumor fraction calculated from short-read sequencing of the same samples. cfDNA size profile, fragmentation patterns, fragment-end composition, and nucleosome profiling near transcription start sites in plasma and urine exhibited the typical cfDNA features. Additionally, a high proportion of long tumor-derived cfDNA fragments (> 300 bp) are recovered in plasma and urine using ONT sequencing. ONT sequencing is a cost-effective, fast, and deployable approach for obtaining genomic and fragmentomic results from liquid biopsies, allowing the analysis of previously understudied cfDNA populations.

KW - cancer

KW - cell-free DNA

KW - fragmentomics

KW - liquid biopsy

KW - nanopore sequencing

UR - http://www.scopus.com/inward/record.url?scp=85176241629&partnerID=8YFLogxK

U2 - https://doi.org/10.15252/emmm.202217282

DO - https://doi.org/10.15252/emmm.202217282

M3 - Article

C2 - 37942753

SN - 1757-4676

VL - 15

JO - EMBO molecular medicine

JF - EMBO molecular medicine

IS - 12

M1 - e17282

ER -

Real-time analysis of the cancer genome and fragmentome from plasma and urine cell-free DNA using nanopore sequencing

Abstract

Keywords

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