Ketones facilitate transcriptional resolution of secondary DNA structures in premature aging

There is currently no established intervention for Cockayne syndrome, a disease characterized by progressive early onset neurodegeneration with features of premature aging. Here, we tested if acetyl-CoA precursors, citrate and beta-hydroxybutyrate, could reduce features of Cockayne syndrome in three model systems. We identified the gene Helicase 89B as a homologue of CSB in drosophila and found that the ketone beta-hydroxybutyrate rescued features of premature aging in Hel89B deficient flies. In mammals, loss of the citrate carrier Indy exacerbated the phenotype of Csbm/m mice which was rescued by a ketogenic diet. The rescue effect appeared to be mediated through ketone stimulated histone acetylation and facilitation of transcriptional readthrough of secondary DNA structures. These findings link a ketogenic diet with transcriptional resolution of secondary structures and DNA repair. ### Competing Interest Statement The authors have declared no competing interest.