Loss of H3K9 trimethylation leads to premature aging

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Serval ID
serval:BIB_8829CE63F327
Type
Autre: use this type when nothing else fits.
Collection
Publications
Institution
Title
Loss of H3K9 trimethylation leads to premature aging
Author(s)
Mrabti Calida, Yang Na, Desdín-Micó Gabriela, Alonso-Calleja Alejandro, Vílchez-Acosta Alba, Pico Sara, Parras Alberto, Piao Yulan, Schoenfeldt Lucas, Luo Siyuan, Haghani Amin, Brooke Robert, Maza María del Carmen, Branchina Clémence, Yacoub Maroun Céline, von Meyenn Ferdinand, Naveiras Olaia, Horvath Steve, Sen Payel, Ocampo Alejandro
ISSN
2692-8205 (Electronic)
ISSN-L
2692-8205
Issued date
24/07/2024
Language
english
Abstract
Aging is the major risk factor for most human diseases and represents a major socio-economical challenge for modern societies. Despite its importance, the process of aging remains poorly understood. Epigenetic dysregulation has been proposed as a key driver of the aging process. Modifications in transcriptional networks and chromatin structure might be central to age-related functional decline. A prevalent feature described during aging is the overall reduction in heterochromatin, specifically marked by the loss of repressive histone modification, Histone 3 lysine 9 trimethylation (H3K9me3). However, the role of H3K9me3 in aging, especially in mammals, remains unclear. Here we show using a novel mouse strain, (TKOc), carrying a triple knockout of three methyltransferases responsible for H3K9me3 deposition, that the inducible loss of H3K9me3 in adulthood results in premature aging. TKOc mice exhibit reduced lifespan, lower body weight, increased frailty index, multi-organ degeneration, transcriptional changes with significant upregulation of transposable elements, and accelerated epigenetic age. Our data strongly supports the concept that the loss of epigenetic information directly drives the aging process. These findings reveal the importance of epigenetic regulation in aging and suggest that interventions targeting epigenetic modifications could potentially slow down or reverse age-related decline. Understanding the molecular mechanisms underlying the process of aging will be crucial for developing novel therapeutic strategies that can delay the onset of age-associated diseases and preserve human health at old age specially in rapidly aging societies.
Pubmed
Create date
09/08/2024 8:20
Last modification date
09/08/2024 14:54
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