<p>Homologous recombination (HR) deficiency increases sensitivity to DNA-damaging agents that are commonly used to treat cancer<sup><CitationRef CitationID="CR1">1</CitationRef></sup>. In HR-proficient cancers, the metabolic mechanisms that drive response or resistance to DNA-damaging agents remain unclear. Here we have identified that depletion of α-ketoglutarate (αKG) sensitizes HR-proficient cells to DNA-damaging agents by metabolic regulation of histone acetylation. αKG is required for the activity of αKG-dependent dioxygenases<sup><CitationRef CitationID="CR2">2</CitationRef></sup> (αKGDDs), and previous work has focused almost exclusively on the demethylase functions of αKGDD. Using a targeted CRISPR knockout library consisting of 64 αKGDDs, we discovered that trimethyllysine hydroxylase epsilon (TMLHE), the first and rate-limiting enzyme in de novo carnitine synthesis, is necessary for the survival of HR-proficient cells in the presence of DNA-damaging agents. Unexpectedly, αKG-mediated TMLHE-dependent carnitine synthesis was required for histone acetylation and was non-redundant with other nucleo-cytosolic acetyl-CoA-generating pathways. The increase in histone acetylation by means of the αKG–carnitine axis promoted HR-mediated DNA repair through site-specific histone acetylation. Finally, we observed a positive correlation between TMLHE and histone acetylation in patient samples and found that high TMLHE or acetylcarnitine correlates with worse progression-free survival in patients treated with DNA-damaging agents. This study demonstrates for the first time, to our knowledge, that αKG affects site-specific histone acetylation and provides a mechanism of HR proficiency through carnitine synthesis. Moreover, these data provide a metabolic avenue for inducing HR deficiency and promoting sensitivity to DNA-damaging agents.</p>

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αKG-mediated carnitine synthesis drives DNA repair via histone acetylation

  • Apoorva Uboveja,
  • Baixue Yang,
  • Raquel Buj,
  • Amandine Amalric,
  • Hui Wang,
  • Naveen Kumar Tangudu,
  • Aidan R. Cole,
  • Julie A. Disharoon,
  • Richard S. Fang,
  • Evan Levasseur,
  • Miho Naruse,
  • Zhentai Huang,
  • Emily Megill,
  • Daniel S. Kantner,
  • Adam Chatoff,
  • Hafsah Ahmad,
  • Mariola M. Marcinkiewicz,
  • Sarah Graff,
  • Ellen De Pieri,
  • Andrea Andress Huacachino,
  • Frank P. Vendetti,
  • Jeff Danielson,
  • Erika S. Dahl,
  • Jennifer L. Pennise,
  • Esther Elishaev,
  • Alison Jaccard,
  • Lauren Borho,
  • Miriam D. Post,
  • Kristine Cooper,
  • Francesmary Modugno,
  • Nadine Hempel,
  • Wayne Stallaert,
  • Christopher J. Bakkenist,
  • Simone Sidoli,
  • Kathryn E. Wellen,
  • Benjamin G. Bitler,
  • David T. Long,
  • Nathaniel W. Snyder,
  • Katherine M. Aird

摘要

Homologous recombination (HR) deficiency increases sensitivity to DNA-damaging agents that are commonly used to treat cancer1. In HR-proficient cancers, the metabolic mechanisms that drive response or resistance to DNA-damaging agents remain unclear. Here we have identified that depletion of α-ketoglutarate (αKG) sensitizes HR-proficient cells to DNA-damaging agents by metabolic regulation of histone acetylation. αKG is required for the activity of αKG-dependent dioxygenases2 (αKGDDs), and previous work has focused almost exclusively on the demethylase functions of αKGDD. Using a targeted CRISPR knockout library consisting of 64 αKGDDs, we discovered that trimethyllysine hydroxylase epsilon (TMLHE), the first and rate-limiting enzyme in de novo carnitine synthesis, is necessary for the survival of HR-proficient cells in the presence of DNA-damaging agents. Unexpectedly, αKG-mediated TMLHE-dependent carnitine synthesis was required for histone acetylation and was non-redundant with other nucleo-cytosolic acetyl-CoA-generating pathways. The increase in histone acetylation by means of the αKG–carnitine axis promoted HR-mediated DNA repair through site-specific histone acetylation. Finally, we observed a positive correlation between TMLHE and histone acetylation in patient samples and found that high TMLHE or acetylcarnitine correlates with worse progression-free survival in patients treated with DNA-damaging agents. This study demonstrates for the first time, to our knowledge, that αKG affects site-specific histone acetylation and provides a mechanism of HR proficiency through carnitine synthesis. Moreover, these data provide a metabolic avenue for inducing HR deficiency and promoting sensitivity to DNA-damaging agents.