CFAP20 salvages arrested RNAPII from the path of co-directional replisomes

Sidrit Uruci; Daphne E C Boer; Paul W Chrystal; Maxime Lalonde; Andreas Panagopoulos; George Yakoub; Idil Kirdök; Klaas de Lint; Melanie van der Woude; Tiemen J Wendel; Sem J Brussee; Annelotte P Wondergem; Nila K van Overbeek; Nini Schotman; Jolanthe Lingeman; Mats Ljungman; Alexander van Oudenaarden; Haico van Attikum; Alfred C O Vertegaal; Sylvie M Noordermeer; Rob M F Wolthuis; Matthias Altmeyer; Stephan Hamperl; Vincent Tropepe; Jeroen van den Berg; Diana van den Heuvel; Martijn S Luijsterburg

doi:10.1038/s41586-025-09943-7

CFAP20 salvages arrested RNAPII from the path of co-directional replisomes

Sidrit Uruci
, Daphne E C Boer
, Paul W Chrystal
, Maxime Lalonde
, Andreas Panagopoulos
, George Yakoub
, Idil Kirdök
, Klaas de Lint
, Melanie van der Woude
, Tiemen J Wendel
, Sem J Brussee
, Annelotte P Wondergem
, Nila K van Overbeek
, Nini Schotman
, Jolanthe Lingeman
, Mats Ljungman
, Alexander van Oudenaarden
, Haico van Attikum
, Alfred C O Vertegaal
, Sylvie M Noordermeer

Rob M F Wolthuis, Matthias Altmeyer, Stephan Hamperl, Vincent Tropepe, Jeroen van den Berg, Diana van den Heuvel^*, Martijn S Luijsterburg^*

^*Corresponding author for this work

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

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Abstract

Fine-tuning DNA replication and transcription is crucial to prevent collisions between their machineries¹. This is particularly important near promoters, where RNA polymerase II (RNAPII) initiates transcription and frequently arrests, forming R-loops^{2, 3–4}. Arrested RNAPII can obstruct DNA replication, which often initiates near promoters^5,6. The mechanisms that rescue arrested RNAPII during elongation to avoid conflicts with co-directional replisomes remain unclear. Here, using genome-wide approaches and genetic screens, we identify CFAP20 as part of a protective pathway that salvages arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops near promoters, which leads to defects in replication timing and dynamics. These defects stem from accelerated replication-fork speeds that cause a secondary reduction in origin activity. Co-depletion of the Mediator complex or removal of R-loop-engaged RNAPII restores normal replication. Our findings suggest that transcription-dependent fork stalling in cis induces accelerated fork progression in trans, generating single-stranded DNA gaps. We propose that CFAP20 facilitates RNAPII elongation under high levels of Mediator-driven transcription, thereby preventing replisome collisions. This study provides a transcription-centred view of transcription–replication encounters, revealing how locally arrested transcription complexes propagate genome-wide replication phenotypes and defining CFAP20 as a key factor that safeguards genome stability.

Original language	English
Pages (from-to)	1025-1034
Number of pages	10
Journal	Nature
Volume	650
Issue number	8103
Early online date	14 Jan 2026
DOIs	https://doi.org/10.1038/s41586-025-09943-7
Publication status	Published - 26 Feb 2026

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CFAP20 salvages arrested RNAPII from the path of co-directional replisomesFinal published version, 20.3 MBLicence: CC BY-NC-ND

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Uruci, S., Boer, D. E. C., Chrystal, P. W., Lalonde, M., Panagopoulos, A., Yakoub, G., Kirdök, I., de Lint, K., van der Woude, M., Wendel, T. J., Brussee, S. J., Wondergem, A. P., van Overbeek, N. K., Schotman, N., Lingeman, J., Ljungman, M., van Oudenaarden, A., van Attikum, H., Vertegaal, A. C. O., ... Luijsterburg, M. S. (2026). CFAP20 salvages arrested RNAPII from the path of co-directional replisomes. Nature, 650(8103), 1025-1034. https://doi.org/10.1038/s41586-025-09943-7

@article{c41f57c9ebe341a6a54a1f691433f9ef,

title = "CFAP20 salvages arrested RNAPII from the path of co-directional replisomes",

abstract = "Fine-tuning DNA replication and transcription is crucial to prevent collisions between their machineries1. This is particularly important near promoters, where RNA polymerase II (RNAPII) initiates transcription and frequently arrests, forming R-loops2, 3–4. Arrested RNAPII can obstruct DNA replication, which often initiates near promoters5,6. The mechanisms that rescue arrested RNAPII during elongation to avoid conflicts with co-directional replisomes remain unclear. Here, using genome-wide approaches and genetic screens, we identify CFAP20 as part of a protective pathway that salvages arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops near promoters, which leads to defects in replication timing and dynamics. These defects stem from accelerated replication-fork speeds that cause a secondary reduction in origin activity. Co-depletion of the Mediator complex or removal of R-loop-engaged RNAPII restores normal replication. Our findings suggest that transcription-dependent fork stalling in cis induces accelerated fork progression in trans, generating single-stranded DNA gaps. We propose that CFAP20 facilitates RNAPII elongation under high levels of Mediator-driven transcription, thereby preventing replisome collisions. This study provides a transcription-centred view of transcription–replication encounters, revealing how locally arrested transcription complexes propagate genome-wide replication phenotypes and defining CFAP20 as a key factor that safeguards genome stability.",

author = "Sidrit Uruci and Boer, \{Daphne E C\} and Chrystal, \{Paul W\} and Maxime Lalonde and Andreas Panagopoulos and George Yakoub and Idil Kird{\"o}k and \{de Lint\}, Klaas and \{van der Woude\}, Melanie and Wendel, \{Tiemen J\} and Brussee, \{Sem J\} and Wondergem, \{Annelotte P\} and \{van Overbeek\}, \{Nila K\} and Nini Schotman and Jolanthe Lingeman and Mats Ljungman and \{van Oudenaarden\}, Alexander and \{van Attikum\}, Haico and Vertegaal, \{Alfred C O\} and Noordermeer, \{Sylvie M\} and Wolthuis, \{Rob M F\} and Matthias Altmeyer and Stephan Hamperl and Vincent Tropepe and \{van den Berg\}, Jeroen and \{van den Heuvel\}, Diana and Luijsterburg, \{Martijn S\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = feb,

day = "26",

doi = "10.1038/s41586-025-09943-7",

language = "English",

volume = "650",

pages = "1025--1034",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "8103",

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Uruci, S, Boer, DEC, Chrystal, PW, Lalonde, M, Panagopoulos, A, Yakoub, G, Kirdök, I, de Lint, K, van der Woude, M, Wendel, TJ, Brussee, SJ, Wondergem, AP, van Overbeek, NK, Schotman, N, Lingeman, J, Ljungman, M, van Oudenaarden, A, van Attikum, H, Vertegaal, ACO, Noordermeer, SM, Wolthuis, RMF, Altmeyer, M, Hamperl, S, Tropepe, V, van den Berg, J, van den Heuvel, D & Luijsterburg, MS 2026, 'CFAP20 salvages arrested RNAPII from the path of co-directional replisomes', Nature, vol. 650, no. 8103, pp. 1025-1034. https://doi.org/10.1038/s41586-025-09943-7

TY - JOUR

T1 - CFAP20 salvages arrested RNAPII from the path of co-directional replisomes

AU - Uruci, Sidrit

AU - Boer, Daphne E C

AU - Chrystal, Paul W

AU - Lalonde, Maxime

AU - Panagopoulos, Andreas

AU - Yakoub, George

AU - Kirdök, Idil

AU - de Lint, Klaas

AU - van der Woude, Melanie

AU - Wendel, Tiemen J

AU - Brussee, Sem J

AU - Wondergem, Annelotte P

AU - van Overbeek, Nila K

AU - Schotman, Nini

AU - Lingeman, Jolanthe

AU - Ljungman, Mats

AU - van Oudenaarden, Alexander

AU - van Attikum, Haico

AU - Vertegaal, Alfred C O

AU - Noordermeer, Sylvie M

AU - Wolthuis, Rob M F

AU - Altmeyer, Matthias

AU - Hamperl, Stephan

AU - Tropepe, Vincent

AU - van den Berg, Jeroen

AU - van den Heuvel, Diana

AU - Luijsterburg, Martijn S

PY - 2026/2/26

Y1 - 2026/2/26

N2 - Fine-tuning DNA replication and transcription is crucial to prevent collisions between their machineries1. This is particularly important near promoters, where RNA polymerase II (RNAPII) initiates transcription and frequently arrests, forming R-loops2, 3–4. Arrested RNAPII can obstruct DNA replication, which often initiates near promoters5,6. The mechanisms that rescue arrested RNAPII during elongation to avoid conflicts with co-directional replisomes remain unclear. Here, using genome-wide approaches and genetic screens, we identify CFAP20 as part of a protective pathway that salvages arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops near promoters, which leads to defects in replication timing and dynamics. These defects stem from accelerated replication-fork speeds that cause a secondary reduction in origin activity. Co-depletion of the Mediator complex or removal of R-loop-engaged RNAPII restores normal replication. Our findings suggest that transcription-dependent fork stalling in cis induces accelerated fork progression in trans, generating single-stranded DNA gaps. We propose that CFAP20 facilitates RNAPII elongation under high levels of Mediator-driven transcription, thereby preventing replisome collisions. This study provides a transcription-centred view of transcription–replication encounters, revealing how locally arrested transcription complexes propagate genome-wide replication phenotypes and defining CFAP20 as a key factor that safeguards genome stability.

AB - Fine-tuning DNA replication and transcription is crucial to prevent collisions between their machineries1. This is particularly important near promoters, where RNA polymerase II (RNAPII) initiates transcription and frequently arrests, forming R-loops2, 3–4. Arrested RNAPII can obstruct DNA replication, which often initiates near promoters5,6. The mechanisms that rescue arrested RNAPII during elongation to avoid conflicts with co-directional replisomes remain unclear. Here, using genome-wide approaches and genetic screens, we identify CFAP20 as part of a protective pathway that salvages arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops near promoters, which leads to defects in replication timing and dynamics. These defects stem from accelerated replication-fork speeds that cause a secondary reduction in origin activity. Co-depletion of the Mediator complex or removal of R-loop-engaged RNAPII restores normal replication. Our findings suggest that transcription-dependent fork stalling in cis induces accelerated fork progression in trans, generating single-stranded DNA gaps. We propose that CFAP20 facilitates RNAPII elongation under high levels of Mediator-driven transcription, thereby preventing replisome collisions. This study provides a transcription-centred view of transcription–replication encounters, revealing how locally arrested transcription complexes propagate genome-wide replication phenotypes and defining CFAP20 as a key factor that safeguards genome stability.

UR - https://www.scopus.com/pages/publications/105027521823

U2 - 10.1038/s41586-025-09943-7

DO - 10.1038/s41586-025-09943-7

M3 - Article

C2 - 41535461

SN - 0028-0836

VL - 650

SP - 1025

EP - 1034

JO - Nature

JF - Nature

IS - 8103

ER -

CFAP20 salvages arrested RNAPII from the path of co-directional replisomes

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