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DNA damage and transcription stress cause ATP-mediated redesign of metabolism and potentiation of anti-oxidant buffering

Author

Listed:
  • Chiara Milanese

    (Erasmus University Medical Center)

  • Cíntia R. Bombardieri

    (Erasmus University Medical Center)

  • Sara Sepe

    (Erasmus University Medical Center)

  • Sander Barnhoorn

    (Erasmus University Medical Center)

  • César Payán-Goméz

    (Erasmus University Medical Center
    Universidad del Rosario)

  • Donatella Caruso

    (University of Milan)

  • Matteo Audano

    (University of Milan)

  • Silvia Pedretti

    (University of Milan)

  • Wilbert P. Vermeij

    (Princess Máxima Center for Pediatric Oncology)

  • Renata M. C. Brandt

    (Erasmus University Medical Center)

  • Akos Gyenis

    (Erasmus University Medical Center
    University of Cologne)

  • Mirjam M. Wamelink

    (VU University Medical Center)

  • Annelieke S. Wit

    (Erasmus University Medical Center)

  • Roel C. Janssens

    (Erasmus University Medical Center)

  • René Leen

    (Academic Medical Center)

  • André B. P. Kuilenburg

    (Academic Medical Center)

  • Nico Mitro

    (University of Milan)

  • Jan H. J. Hoeijmakers

    (Erasmus University Medical Center
    Princess Máxima Center for Pediatric Oncology
    University of Cologne
    Princess Máxima Center)

  • Pier G. Mastroberardino

    (Erasmus University Medical Center
    University of L’Aquila)

Abstract

Accumulation of DNA lesions causing transcription stress is associated with natural and accelerated aging and culminates with profound metabolic alterations. Our understanding of the mechanisms governing metabolic redesign upon genomic instability, however, is highly rudimentary. Using Ercc1-defective mice and Xpg knock-out mice, we demonstrate that combined defects in transcription-coupled DNA repair (TCR) and in nucleotide excision repair (NER) directly affect bioenergetics due to declined transcription, leading to increased ATP levels. This in turn inhibits glycolysis allosterically and favors glucose rerouting through the pentose phosphate shunt, eventually enhancing production of NADPH-reducing equivalents. In NER/TCR-defective mutants, augmented NADPH is not counterbalanced by increased production of pro-oxidants and thus pentose phosphate potentiation culminates in an over-reduced redox state. Skin fibroblasts from the TCR disease Cockayne syndrome confirm results in animal models. Overall, these findings unravel a mechanism connecting DNA damage and transcriptional stress to metabolic redesign and protective antioxidant defenses.

Suggested Citation

  • Chiara Milanese & Cíntia R. Bombardieri & Sara Sepe & Sander Barnhoorn & César Payán-Goméz & Donatella Caruso & Matteo Audano & Silvia Pedretti & Wilbert P. Vermeij & Renata M. C. Brandt & Akos Gyenis, 2019. "DNA damage and transcription stress cause ATP-mediated redesign of metabolism and potentiation of anti-oxidant buffering," Nature Communications, Nature, vol. 10(1), pages 1-16, December.
    • Handle: RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-12640-5
    DOI: 10.1038/s41467-019-12640-5
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