Error-corrected flow-based sequencing at whole-genome scale and its application to circulating cell-free DNA profiling

Alexandre Pellan Cheng; Adam J. Widman; Anushri Arora; Itai Rusinek; Aaron Sossin; Srinivas Rajagopalan; Nicholas Midler; William F. Hooper; Rebecca M. Murray; Daniel Halmos; Theophile Langanay; Hoyin Chu; Giorgio Inghirami; Catherine Potenski; Soren Germer; Melissa Marton; Dina Manaa; Adrienne Helland; Rob Furatero; Jaime McClintock; Lara Winterkorn; Zoe Steinsnyder; Yohyoh Wang; Asrar I. Alimohamed; Murtaza S. Malbari; Ashish Saxena; Margaret K. Callahan; Dennie T. Frederick; Lavinia Spain; Michael Sigouros; Jyothi Manohar; Abigail King; David Wilkes; John Otilano; Olivier Elemento; Juan Miguel Mosquera; Ariel Jaimovich; Doron Lipson; Samra Turajlic; Michael C. Zody; Nasser K. Altorki; Jedd D. Wolchok; Michael A. Postow; Nicolas Robine; Bishoy M. Faltas; Genevieve Boland; Dan A. Landau

doi:10.1038/s41592-025-02648-9

Error-corrected flow-based sequencing at whole-genome scale and its application to circulating cell-free DNA profiling

Alexandre Pellan Cheng
, Adam J. Widman
, Anushri Arora
, Itai Rusinek
, Aaron Sossin
, Srinivas Rajagopalan
, Nicholas Midler
, William F. Hooper
, Rebecca M. Murray
, Daniel Halmos
, Theophile Langanay
, Hoyin Chu
, Giorgio Inghirami
, Catherine Potenski
, Soren Germer
, Melissa Marton
, Dina Manaa
, Adrienne Helland
, Rob Furatero
, Jaime McClintock

Lara Winterkorn, Zoe Steinsnyder, Yohyoh Wang, Asrar I. Alimohamed, Murtaza S. Malbari, Ashish Saxena, Margaret K. Callahan, Dennie T. Frederick, Lavinia Spain, Michael Sigouros, Jyothi Manohar, Abigail King, David Wilkes, John Otilano, Olivier Elemento, Juan Miguel Mosquera, Ariel Jaimovich, Doron Lipson, Samra Turajlic, Michael C. Zody, Nasser K. Altorki, Jedd D. Wolchok, Michael A. Postow, Nicolas Robine, Bishoy M. Faltas, Genevieve Boland, Dan A. Landau

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7 Citations (Scopus)

Résumé

Differentiating sequencing errors from true variants is a central genomics challenge, calling for error suppression strategies that balance costs and sensitivity. For example, circulating cell-free DNA (ccfDNA) sequencing for cancer monitoring is limited by sparsity of circulating tumor DNA, abundance of genomic material in samples and preanalytical error rates. Whole-genome sequencing (WGS) can overcome the low abundance of ccfDNA by integrating signals across the mutation landscape, but higher costs limit its wide adoption. Here, we applied deep (~120×) lower-cost WGS (Ultima Genomics) for tumor-informed circulating tumor DNA detection within the part-per-million range. We further leveraged lower-cost sequencing by developing duplex error-corrected WGS of ccfDNA, achieving 7.7 × 10⁻⁷ error rates, allowing us to assess disease burden in individuals with melanoma and urothelial cancer without matched tumor sequencing. This error-corrected WGS approach will have broad applicability across genomics, allowing for accurate calling of low-abundance variants at efficient cost and enabling deeper mapping of somatic mosaicism as an emerging central aspect of aging and disease.

langue originale	Anglais
Numéro d'article	5220
Pages (de - à)	973-981
Nombre de pages	9
journal	Nature Methods
Volume	22
Numéro de publication	5
Les DOIs	https://doi.org/10.1038/s41592-025-02648-9
état	Publié - mai 2025

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10.1038/s41592-025-02648-9

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Cheng, A. P., Widman, A. J., Arora, A., Rusinek, I., Sossin, A., Rajagopalan, S., Midler, N., Hooper, W. F., Murray, R. M., Halmos, D., Langanay, T., Chu, H., Inghirami, G., Potenski, C., Germer, S., Marton, M., Manaa, D., Helland, A., Furatero, R., ... Landau, D. A. (2025). Error-corrected flow-based sequencing at whole-genome scale and its application to circulating cell-free DNA profiling. Nature Methods, 22(5), 973-981. Article 5220. https://doi.org/10.1038/s41592-025-02648-9

@article{9646937a6be549d3a515ae804c29102b,

title = "Error-corrected flow-based sequencing at whole-genome scale and its application to circulating cell-free DNA profiling",

abstract = "Differentiating sequencing errors from true variants is a central genomics challenge, calling for error suppression strategies that balance costs and sensitivity. For example, circulating cell-free DNA (ccfDNA) sequencing for cancer monitoring is limited by sparsity of circulating tumor DNA, abundance of genomic material in samples and preanalytical error rates. Whole-genome sequencing (WGS) can overcome the low abundance of ccfDNA by integrating signals across the mutation landscape, but higher costs limit its wide adoption. Here, we applied deep (\textasciitilde{}120×) lower-cost WGS (Ultima Genomics) for tumor-informed circulating tumor DNA detection within the part-per-million range. We further leveraged lower-cost sequencing by developing duplex error-corrected WGS of ccfDNA, achieving 7.7 × 10−7 error rates, allowing us to assess disease burden in individuals with melanoma and urothelial cancer without matched tumor sequencing. This error-corrected WGS approach will have broad applicability across genomics, allowing for accurate calling of low-abundance variants at efficient cost and enabling deeper mapping of somatic mosaicism as an emerging central aspect of aging and disease.",

author = "Cheng, \{Alexandre Pellan\} and Widman, \{Adam J.\} and Anushri Arora and Itai Rusinek and Aaron Sossin and Srinivas Rajagopalan and Nicholas Midler and Hooper, \{William F.\} and Murray, \{Rebecca M.\} and Daniel Halmos and Theophile Langanay and Hoyin Chu and Giorgio Inghirami and Catherine Potenski and Soren Germer and Melissa Marton and Dina Manaa and Adrienne Helland and Rob Furatero and Jaime McClintock and Lara Winterkorn and Zoe Steinsnyder and Yohyoh Wang and Alimohamed, \{Asrar I.\} and Malbari, \{Murtaza S.\} and Ashish Saxena and Callahan, \{Margaret K.\} and Frederick, \{Dennie T.\} and Lavinia Spain and Michael Sigouros and Jyothi Manohar and Abigail King and David Wilkes and John Otilano and Olivier Elemento and Mosquera, \{Juan Miguel\} and Ariel Jaimovich and Doron Lipson and Samra Turajlic and Zody, \{Michael C.\} and Altorki, \{Nasser K.\} and Wolchok, \{Jedd D.\} and Postow, \{Michael A.\} and Nicolas Robine and Faltas, \{Bishoy M.\} and Genevieve Boland and Landau, \{Dan A.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature America, Inc. 2025.",

year = "2025",

month = may,

doi = "10.1038/s41592-025-02648-9",

language = "English",

volume = "22",

pages = "973--981",

journal = "Nature Methods",

issn = "1548-7091",

publisher = "Nature Research",

number = "5",

}

Cheng, AP, Widman, AJ, Arora, A, Rusinek, I, Sossin, A, Rajagopalan, S, Midler, N, Hooper, WF, Murray, RM, Halmos, D, Langanay, T, Chu, H, Inghirami, G, Potenski, C, Germer, S, Marton, M, Manaa, D, Helland, A, Furatero, R, McClintock, J, Winterkorn, L, Steinsnyder, Z, Wang, Y, Alimohamed, AI, Malbari, MS, Saxena, A, Callahan, MK, Frederick, DT, Spain, L, Sigouros, M, Manohar, J, King, A, Wilkes, D, Otilano, J, Elemento, O, Mosquera, JM, Jaimovich, A, Lipson, D, Turajlic, S, Zody, MC, Altorki, NK, Wolchok, JD, Postow, MA, Robine, N, Faltas, BM, Boland, G & Landau, DA 2025, 'Error-corrected flow-based sequencing at whole-genome scale and its application to circulating cell-free DNA profiling', Nature Methods, VOL. 22, Numéro 5, 5220, p. 973-981. https://doi.org/10.1038/s41592-025-02648-9

Error-corrected flow-based sequencing at whole-genome scale and its application to circulating cell-free DNA profiling. / Cheng, Alexandre Pellan; Widman, Adam J.; Arora, Anushri et al.
Dans: Nature Methods, Vol 22, Numéro 5, 5220, 05.2025, p. 973-981.

Résultats de recherche: Contribution à un journal › Article publié dans une revue, révisé par les pairs › Revue par des pairs

TY - JOUR

T1 - Error-corrected flow-based sequencing at whole-genome scale and its application to circulating cell-free DNA profiling

AU - Cheng, Alexandre Pellan

AU - Widman, Adam J.

AU - Arora, Anushri

AU - Rusinek, Itai

AU - Sossin, Aaron

AU - Rajagopalan, Srinivas

AU - Midler, Nicholas

AU - Hooper, William F.

AU - Murray, Rebecca M.

AU - Halmos, Daniel

AU - Langanay, Theophile

AU - Chu, Hoyin

AU - Inghirami, Giorgio

AU - Potenski, Catherine

AU - Germer, Soren

AU - Marton, Melissa

AU - Manaa, Dina

AU - Helland, Adrienne

AU - Furatero, Rob

AU - McClintock, Jaime

AU - Winterkorn, Lara

AU - Steinsnyder, Zoe

AU - Wang, Yohyoh

AU - Alimohamed, Asrar I.

AU - Malbari, Murtaza S.

AU - Saxena, Ashish

AU - Callahan, Margaret K.

AU - Frederick, Dennie T.

AU - Spain, Lavinia

AU - Sigouros, Michael

AU - Manohar, Jyothi

AU - King, Abigail

AU - Wilkes, David

AU - Otilano, John

AU - Elemento, Olivier

AU - Mosquera, Juan Miguel

AU - Jaimovich, Ariel

AU - Lipson, Doron

AU - Turajlic, Samra

AU - Zody, Michael C.

AU - Altorki, Nasser K.

AU - Wolchok, Jedd D.

AU - Postow, Michael A.

AU - Robine, Nicolas

AU - Faltas, Bishoy M.

AU - Boland, Genevieve

AU - Landau, Dan A.

PY - 2025/5

Y1 - 2025/5

N2 - Differentiating sequencing errors from true variants is a central genomics challenge, calling for error suppression strategies that balance costs and sensitivity. For example, circulating cell-free DNA (ccfDNA) sequencing for cancer monitoring is limited by sparsity of circulating tumor DNA, abundance of genomic material in samples and preanalytical error rates. Whole-genome sequencing (WGS) can overcome the low abundance of ccfDNA by integrating signals across the mutation landscape, but higher costs limit its wide adoption. Here, we applied deep (~120×) lower-cost WGS (Ultima Genomics) for tumor-informed circulating tumor DNA detection within the part-per-million range. We further leveraged lower-cost sequencing by developing duplex error-corrected WGS of ccfDNA, achieving 7.7 × 10−7 error rates, allowing us to assess disease burden in individuals with melanoma and urothelial cancer without matched tumor sequencing. This error-corrected WGS approach will have broad applicability across genomics, allowing for accurate calling of low-abundance variants at efficient cost and enabling deeper mapping of somatic mosaicism as an emerging central aspect of aging and disease.

AB - Differentiating sequencing errors from true variants is a central genomics challenge, calling for error suppression strategies that balance costs and sensitivity. For example, circulating cell-free DNA (ccfDNA) sequencing for cancer monitoring is limited by sparsity of circulating tumor DNA, abundance of genomic material in samples and preanalytical error rates. Whole-genome sequencing (WGS) can overcome the low abundance of ccfDNA by integrating signals across the mutation landscape, but higher costs limit its wide adoption. Here, we applied deep (~120×) lower-cost WGS (Ultima Genomics) for tumor-informed circulating tumor DNA detection within the part-per-million range. We further leveraged lower-cost sequencing by developing duplex error-corrected WGS of ccfDNA, achieving 7.7 × 10−7 error rates, allowing us to assess disease burden in individuals with melanoma and urothelial cancer without matched tumor sequencing. This error-corrected WGS approach will have broad applicability across genomics, allowing for accurate calling of low-abundance variants at efficient cost and enabling deeper mapping of somatic mosaicism as an emerging central aspect of aging and disease.

UR - https://www.scopus.com/pages/publications/105002353221

U2 - 10.1038/s41592-025-02648-9

DO - 10.1038/s41592-025-02648-9

M3 - Journal Article

AN - SCOPUS:105002353221

SN - 1548-7091

VL - 22

SP - 973

EP - 981

JO - Nature Methods

JF - Nature Methods

IS - 5

M1 - 5220

ER -