Authors
Urgel-Solas, J., Benito, A., Ortet, L., Kourtis, S., Abad, E., Coll Manzano, A., Shevzov-Zebrun, A., Reiter Elbaek, C., Martinez, C., Vander Heiden, M., Sdelci, S., Janic, A.
Abstract
Metabolic adaptation is essential for cells experiencing chronic genomic stress, yet how such adaptations are organized at the nuclear level remains poorly understood. Loss of TP53 is associated with elevated genomic instability, DNA damage and altered metabolic requirements, creating context specific dependencies. Here, we identify a requirement for de novo purine biosynthesis in TP53-deficient cells, with a pronounced dependence on adenosine related metabolism. Perturbation of purine synthesis increases DNA damage and reduces nuclear ATP availability, particularly in TP53-deficient cells, and is accompanied by a rapid increase in histone methylation. This chromatin response is also induced by acute DNA damage and occurs with fast kinetics, indicating that histone methylation is an early, intrinsic feature of the nuclear stress response rather than a secondary epigenetic remodeling. Interfering with histone methylation is associated with reduced nuclear ATP levels and impaired DNA damage resolution, linking chromatin state to nuclear energy homeostasis. Genetic disruption of the purine biosynthesis enzyme PFAS selectively impairs the growth of TP53-deficient tumours in vivo, establishing the physiological relevance of this metabolic dependency. Together, these findings reveal nuclear adenosine metabolism as a compartmentalised adaptive response to genotoxic stress and highlight chromatin associated methylation as a key feature of nuclear metabolic regulation unmasked by TP53 loss.
Preprint server:
bioRxiv
The authors list and abstract were imported from bioRxiv on 08 Jul 2026.
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