Tracking clonal evolution during treatment in ovarian cancer using cell-free DNA

Marc J. Williams; Ignacio Vázquez-García; Grittney Tam; Michelle Wu; Nancy Varice; Eliyahu Havasov; Hongyu Shi; Duaa H. Al-Rawi; Gryte Satas; Hannah J. Lees; Jake June Koo Lee; Matthew A. Myers; Matthew Zatzman; Nicole Rusk; Emily Ali; Ronak H. Shah; Michael F. Berger; Neeman Mohibullah; Yulia Lakhman; Dennis S. Chi; Nadeem R. Abu-Rustum; Carol Aghajanian; Andrew McPherson; Dmitriy Zamarin; Brian Loomis; Britta Weigelt; Claire F. Friedman; Sohrab P. Shah

doi:10.1038/s41586-025-09580-0

Tracking clonal evolution during treatment in ovarian cancer using cell-free DNA

Marc J. Williams
, Ignacio Vázquez-García
, Grittney Tam
, Michelle Wu
, Nancy Varice
, Eliyahu Havasov
, Hongyu Shi
, Duaa H. Al-Rawi
, Gryte Satas
, Hannah J. Lees
, Jake June Koo Lee
, Matthew A. Myers
, Matthew Zatzman
, Nicole Rusk
, Emily Ali
, Ronak H. Shah
, Michael F. Berger
, Neeman Mohibullah
, Yulia Lakhman
, Dennis S. Chi

Nadeem R. Abu-Rustum, Carol Aghajanian, Andrew McPherson, Dmitriy Zamarin, Brian Loomis, Britta Weigelt, Claire F. Friedman, Sohrab P. Shah

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

2 Scopus citations

Abstract

Emergence of drug resistance is the main cause of therapeutic failure in patients with high-grade serous ovarian cancer (HGSOC)¹. To study drug resistance in patients, we developed CloneSeq-SV, which combines single-cell whole-genome sequencing² with targeted deep sequencing of clone-specific genomic structural variants in time-series cell-free DNA. CloneSeq-SV exploits tumour clone-specific structural variants as highly sensitive endogenous cell-free DNA markers, enabling the relative abundance measurements and evolutionary analysis of co-existing clonal populations over the therapeutic time course. Here, using this approach, we studied 18 patients with HGSOC over a multi-year period from diagnosis to recurrence and showed that drug resistance typically arose from selective expansion of a single or small subset of clones present at diagnosis. Drug-resistant clones frequently showed interpretable and distinctive genomic features, including chromothripsis, whole-genome doubling, and high-level amplifications of oncogenes such as CCNE1, RAB25, MYC and NOTCH3. Phenotypic analysis of matched single-cell RNA sequencing data³ indicated pre-existing and clone-specific transcriptional states such as upregulation of epithelial-to-mesenchymal transition and VEGF pathways, linked to drug resistance. In one notable case, clone-specific ERBB2 amplification affected the efficacy of a secondary targeted therapy with a positive patient outcome. Together, our findings indicate that drug-resistant states in HGSOC pre-exist at diagnosis, leading to positive selection and reduced clonal complexity at relapse. We suggest these findings motivate investigation of evolution-informed adaptive treatment regimens to ablate drug resistance in future HGSOC studies.

Original language	English
Pages (from-to)	757-765
Number of pages	9
Journal	Nature
Volume	647
Issue number	8090
DOIs	https://doi.org/10.1038/s41586-025-09580-0
State	Published - 20 Nov 2025

Access to Document

10.1038/s41586-025-09580-0

Cite this

Williams, M. J., Vázquez-García, I., Tam, G., Wu, M., Varice, N., Havasov, E., Shi, H., Al-Rawi, D. H., Satas, G., Lees, H. J., Lee, J. J. K., Myers, M. A., Zatzman, M., Rusk, N., Ali, E., Shah, R. H., Berger, M. F., Mohibullah, N., Lakhman, Y., ... Shah, S. P. (2025). Tracking clonal evolution during treatment in ovarian cancer using cell-free DNA. Nature, 647(8090), 757-765. https://doi.org/10.1038/s41586-025-09580-0

@article{022d29aae1a94c0c8b0116475d447316,

title = "Tracking clonal evolution during treatment in ovarian cancer using cell-free DNA",

abstract = "Emergence of drug resistance is the main cause of therapeutic failure in patients with high-grade serous ovarian cancer (HGSOC)1. To study drug resistance in patients, we developed CloneSeq-SV, which combines single-cell whole-genome sequencing2 with targeted deep sequencing of clone-specific genomic structural variants in time-series cell-free DNA. CloneSeq-SV exploits tumour clone-specific structural variants as highly sensitive endogenous cell-free DNA markers, enabling the relative abundance measurements and evolutionary analysis of co-existing clonal populations over the therapeutic time course. Here, using this approach, we studied 18 patients with HGSOC over a multi-year period from diagnosis to recurrence and showed that drug resistance typically arose from selective expansion of a single or small subset of clones present at diagnosis. Drug-resistant clones frequently showed interpretable and distinctive genomic features, including chromothripsis, whole-genome doubling, and high-level amplifications of oncogenes such as CCNE1, RAB25, MYC and NOTCH3. Phenotypic analysis of matched single-cell RNA sequencing data3 indicated pre-existing and clone-specific transcriptional states such as upregulation of epithelial-to-mesenchymal transition and VEGF pathways, linked to drug resistance. In one notable case, clone-specific ERBB2 amplification affected the efficacy of a secondary targeted therapy with a positive patient outcome. Together, our findings indicate that drug-resistant states in HGSOC pre-exist at diagnosis, leading to positive selection and reduced clonal complexity at relapse. We suggest these findings motivate investigation of evolution-informed adaptive treatment regimens to ablate drug resistance in future HGSOC studies.",

author = "Williams, \{Marc J.\} and Ignacio V{\'a}zquez-Garc{\'i}a and Grittney Tam and Michelle Wu and Nancy Varice and Eliyahu Havasov and Hongyu Shi and Al-Rawi, \{Duaa H.\} and Gryte Satas and Lees, \{Hannah J.\} and Lee, \{Jake June Koo\} and Myers, \{Matthew A.\} and Matthew Zatzman and Nicole Rusk and Emily Ali and Shah, \{Ronak H.\} and Berger, \{Michael F.\} and Neeman Mohibullah and Yulia Lakhman and Chi, \{Dennis S.\} and Abu-Rustum, \{Nadeem R.\} and Carol Aghajanian and Andrew McPherson and Dmitriy Zamarin and Brian Loomis and Britta Weigelt and Friedman, \{Claire F.\} and Shah, \{Sohrab P.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = nov,

day = "20",

doi = "10.1038/s41586-025-09580-0",

language = "English",

volume = "647",

pages = "757--765",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "8090",

}

Williams, MJ, Vázquez-García, I, Tam, G, Wu, M, Varice, N, Havasov, E, Shi, H, Al-Rawi, DH, Satas, G, Lees, HJ, Lee, JJK, Myers, MA, Zatzman, M, Rusk, N, Ali, E, Shah, RH, Berger, MF, Mohibullah, N, Lakhman, Y, Chi, DS, Abu-Rustum, NR, Aghajanian, C, McPherson, A, Zamarin, D, Loomis, B, Weigelt, B, Friedman, CF & Shah, SP 2025, 'Tracking clonal evolution during treatment in ovarian cancer using cell-free DNA', Nature, vol. 647, no. 8090, pp. 757-765. https://doi.org/10.1038/s41586-025-09580-0

TY - JOUR

T1 - Tracking clonal evolution during treatment in ovarian cancer using cell-free DNA

AU - Williams, Marc J.

AU - Vázquez-García, Ignacio

AU - Tam, Grittney

AU - Wu, Michelle

AU - Varice, Nancy

AU - Havasov, Eliyahu

AU - Shi, Hongyu

AU - Al-Rawi, Duaa H.

AU - Satas, Gryte

AU - Lees, Hannah J.

AU - Lee, Jake June Koo

AU - Myers, Matthew A.

AU - Zatzman, Matthew

AU - Rusk, Nicole

AU - Ali, Emily

AU - Shah, Ronak H.

AU - Berger, Michael F.

AU - Mohibullah, Neeman

AU - Lakhman, Yulia

AU - Chi, Dennis S.

AU - Abu-Rustum, Nadeem R.

AU - Aghajanian, Carol

AU - McPherson, Andrew

AU - Zamarin, Dmitriy

AU - Loomis, Brian

AU - Weigelt, Britta

AU - Friedman, Claire F.

AU - Shah, Sohrab P.

PY - 2025/11/20

Y1 - 2025/11/20

N2 - Emergence of drug resistance is the main cause of therapeutic failure in patients with high-grade serous ovarian cancer (HGSOC)1. To study drug resistance in patients, we developed CloneSeq-SV, which combines single-cell whole-genome sequencing2 with targeted deep sequencing of clone-specific genomic structural variants in time-series cell-free DNA. CloneSeq-SV exploits tumour clone-specific structural variants as highly sensitive endogenous cell-free DNA markers, enabling the relative abundance measurements and evolutionary analysis of co-existing clonal populations over the therapeutic time course. Here, using this approach, we studied 18 patients with HGSOC over a multi-year period from diagnosis to recurrence and showed that drug resistance typically arose from selective expansion of a single or small subset of clones present at diagnosis. Drug-resistant clones frequently showed interpretable and distinctive genomic features, including chromothripsis, whole-genome doubling, and high-level amplifications of oncogenes such as CCNE1, RAB25, MYC and NOTCH3. Phenotypic analysis of matched single-cell RNA sequencing data3 indicated pre-existing and clone-specific transcriptional states such as upregulation of epithelial-to-mesenchymal transition and VEGF pathways, linked to drug resistance. In one notable case, clone-specific ERBB2 amplification affected the efficacy of a secondary targeted therapy with a positive patient outcome. Together, our findings indicate that drug-resistant states in HGSOC pre-exist at diagnosis, leading to positive selection and reduced clonal complexity at relapse. We suggest these findings motivate investigation of evolution-informed adaptive treatment regimens to ablate drug resistance in future HGSOC studies.

AB - Emergence of drug resistance is the main cause of therapeutic failure in patients with high-grade serous ovarian cancer (HGSOC)1. To study drug resistance in patients, we developed CloneSeq-SV, which combines single-cell whole-genome sequencing2 with targeted deep sequencing of clone-specific genomic structural variants in time-series cell-free DNA. CloneSeq-SV exploits tumour clone-specific structural variants as highly sensitive endogenous cell-free DNA markers, enabling the relative abundance measurements and evolutionary analysis of co-existing clonal populations over the therapeutic time course. Here, using this approach, we studied 18 patients with HGSOC over a multi-year period from diagnosis to recurrence and showed that drug resistance typically arose from selective expansion of a single or small subset of clones present at diagnosis. Drug-resistant clones frequently showed interpretable and distinctive genomic features, including chromothripsis, whole-genome doubling, and high-level amplifications of oncogenes such as CCNE1, RAB25, MYC and NOTCH3. Phenotypic analysis of matched single-cell RNA sequencing data3 indicated pre-existing and clone-specific transcriptional states such as upregulation of epithelial-to-mesenchymal transition and VEGF pathways, linked to drug resistance. In one notable case, clone-specific ERBB2 amplification affected the efficacy of a secondary targeted therapy with a positive patient outcome. Together, our findings indicate that drug-resistant states in HGSOC pre-exist at diagnosis, leading to positive selection and reduced clonal complexity at relapse. We suggest these findings motivate investigation of evolution-informed adaptive treatment regimens to ablate drug resistance in future HGSOC studies.

UR - https://www.scopus.com/pages/publications/105017740332

U2 - 10.1038/s41586-025-09580-0

DO - 10.1038/s41586-025-09580-0

M3 - Article

C2 - 41034582

AN - SCOPUS:105017740332

SN - 0028-0836

VL - 647

SP - 757

EP - 765

JO - Nature

JF - Nature

IS - 8090

ER -

Tracking clonal evolution during treatment in ovarian cancer using cell-free DNA

Abstract

Access to Document

Fingerprint

Cite this