Abstract
Changes in histone modifications are an attractive model through which environmental signals, such as diet, could be integrated in the cell for regulating its lifespan. However, evidence linking dietary interventions with specific alterations in histone modifications that subsequently affect lifespan remains elusive. We show here that deletion of histone N‐alpha‐terminal acetyltransferase Nat4 and loss of its associated H4 N‐terminal acetylation (N‐acH4) extend yeast replicative lifespan. Notably, nat4Δ‐induced longevity is epistatic to the effects of calorie restriction (CR). Consistent with this, (i) Nat4 expression is downregulated and the levels of N‐acH4 within chromatin are reduced upon CR, (ii) constitutive expression of Nat4 and maintenance of N‐acH4 levels reduces the extension of lifespan mediated by CR, and (iii) transcriptome analysis indicates that nat4Δ largely mimics the effects of CR, especially in the induction of stress‐response genes. We further show that nicotinamidase Pnc1, which is typically upregulated under CR, is required for nat4Δ‐mediated longevity. Collectively, these findings establish histone N‐acH4 as a regulator of cellular lifespan that links CR to increased stress resistance and longevity.
Highlights
The eukaryotic genome is packaged into chromatin, a macromolecular structure consisting of nucleosomes as the basic repeating unit
We found that calorie restriction (CR) reduces significantly the expression of NAT4 (Fig 1A)
NAT4 expression is not significantly downregulated by CR when its transcription is constitutively driven by the CR-insensitive promoter STE5, confirming that endogenous NAT4 is regulated by glucose deprivation (Fig 1A, see Pste5-NAT4)
Summary
The eukaryotic genome is packaged into chromatin, a macromolecular structure consisting of nucleosomes as the basic repeating unit. Histones undergo several post-translational modifications that can induce changes in chromatin structure and regulate DNA-based processes like transcription [1]. Alterations in histone modifications contribute to the transcriptional changes that are associated with aging [6,7,11,12,13,14]. Considering that these epigenetic marks respond to environmental stimuli [15], histone modifications could act as an interface through which extracellular signals, like dietary manipulations or stress, may impact on lifespan
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