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CDK12 regulates DNA repair genes by suppressing intronic polyadenylation

Author

Listed:
  • Sara J. Dubbury

    (Massachusetts Institute of Technology
    Massachusetts Institute of Technology)

  • Paul L. Boutz

    (Massachusetts Institute of Technology
    University of Rochester School of Medicine and Dentistry)

  • Phillip A. Sharp

    (Massachusetts Institute of Technology
    Massachusetts Institute of Technology)

Abstract

Mutations that attenuate homologous recombination (HR)-mediated repair promote tumorigenesis and sensitize cells to chemotherapeutics that cause replication fork collapse, a phenotype known as ‘BRCAness’1. BRCAness tumours arise from loss-of-function mutations in 22 genes1. Of these genes, all but one (CDK12) function directly in the HR repair pathway1. CDK12 phosphorylates serine 2 of the RNA polymerase II C-terminal domain heptapeptide repeat2–7, a modification that regulates transcription elongation, splicing, and cleavage and polyadenylation8,9. Genome-wide expression studies suggest that depletion of CDK12 abrogates the expression of several HR genes relatively specifically, thereby blunting HR repair3–7,10,11. This observation suggests that the mutational status of CDK12 may predict sensitivity to targeted treatments against BRCAness, such as PARP1 inhibitors, and that CDK12 inhibitors may induce sensitization of HR-competent tumours to these treatments6,7,10,11. Despite growing clinical interest, the mechanism by which CDK12 regulates HR genes remains unknown. Here we show that CDK12 globally suppresses intronic polyadenylation events in mouse embryonic stem cells, enabling the production of full-length gene products. Many HR genes harbour more intronic polyadenylation sites than other expressed genes, and these sites are particularly sensitive to loss of CDK12. The cumulative effect of these sites accounts for the enhanced sensitivity of HR gene expression to CDK12 loss, and we find that this mechanism is conserved in human tumours that contain loss-of-function CDK12 mutations. This work clarifies the function of CDK12 and underscores its potential both as a chemotherapeutic target and as a tumour biomarker.

Suggested Citation

  • Sara J. Dubbury & Paul L. Boutz & Phillip A. Sharp, 2018. "CDK12 regulates DNA repair genes by suppressing intronic polyadenylation," Nature, Nature, vol. 564(7734), pages 141-145, December.
    • Handle: RePEc:nat:nature:v:564:y:2018:i:7734:d:10.1038_s41586-018-0758-y
    DOI: 10.1038/s41586-018-0758-y
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    Citations

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    Cited by:

    1. Maria C. Tanzer & Isabell Bludau & Che A. Stafford & Veit Hornung & Matthias Mann, 2021. "Phosphoproteome profiling uncovers a key role for CDKs in TNF signaling," Nature Communications, Nature, vol. 12(1), pages 1-15, December.
    2. M. G. Filippone & D. Gaglio & R. Bonfanti & F. A. Tucci & E. Ceccacci & R. Pennisi & M. Bonanomi & G. Jodice & M. Tillhon & F. Montani & G. Bertalot & S. Freddi & M. Vecchi & A. Taglialatela & M. Roma, 2022. "CDK12 promotes tumorigenesis but induces vulnerability to therapies inhibiting folate one-carbon metabolism in breast cancer," Nature Communications, Nature, vol. 13(1), pages 1-19, December.
    3. Laura Curti & Sara Rohban & Nicola Bianchi & Ottavio Croci & Adrian Andronache & Sara Barozzi & Michela Mattioli & Fernanda Ricci & Elena Pastori & Silvia Sberna & Simone Bellotti & Anna Accialini & R, 2024. "CDK12 controls transcription at damaged genes and prevents MYC-induced transcription-replication conflicts," Nature Communications, Nature, vol. 15(1), pages 1-18, December.
    4. Abdallah Gaballa & Anneli Gebhardt-Wolf & Bastian Krenz & Greta Mattavelli & Mara John & Giacomo Cossa & Silvia Andreani & Christina Schülein-Völk & Francisco Montesinos & Raphael Vidal & Carolin Kast, 2024. "PAF1c links S-phase progression to immune evasion and MYC function in pancreatic carcinoma," Nature Communications, Nature, vol. 15(1), pages 1-18, December.
    5. Yange Cui & Luyang Wang & Qingbao Ding & Jihae Shin & Joel Cassel & Qin Liu & Joseph M. Salvino & Bin Tian, 2023. "Elevated pre-mRNA 3′ end processing activity in cancer cells renders vulnerability to inhibition of cleavage and polyadenylation," Nature Communications, Nature, vol. 14(1), pages 1-20, December.
    6. Buki Kwon & Mervin M. Fansler & Neil D. Patel & Jihye Lee & Weirui Ma & Christine Mayr, 2022. "Enhancers regulate 3′ end processing activity to control expression of alternative 3′UTR isoforms," Nature Communications, Nature, vol. 13(1), pages 1-14, December.
    7. Kenzui Taniue & Anzu Sugawara & Chao Zeng & Han Han & Xinyue Gao & Yuki Shimoura & Atsuko Nakanishi Ozeki & Rena Onoguchi-Mizutani & Masahide Seki & Yutaka Suzuki & Michiaki Hamada & Nobuyoshi Akimits, 2024. "The MTR4/hnRNPK complex surveils aberrant polyadenylated RNAs with multiple exons," Nature Communications, Nature, vol. 15(1), pages 1-13, December.
    8. Thibault Houles & Geneviève Lavoie & Sami Nourreddine & Winnie Cheung & Éric Vaillancourt-Jean & Célia M. Guérin & Mathieu Bouttier & Benoit Grondin & Sichun Lin & Marc K. Saba-El-Leil & Stephane Ange, 2022. "CDK12 is hyperactivated and a synthetic-lethal target in BRAF-mutated melanoma," Nature Communications, Nature, vol. 13(1), pages 1-16, December.

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