Document Type
Article
Publication Date
10-1-2024
Original Citation
Di Francesco A,
Deighan A,
Litichevskiy L,
Chen Z,
Luciano A,
Robinson L,
Garland G,
Donato H,
Vincent M,
Schott WH,
Wright K,
Raj A,
Prateek G,
Mullis M,
Hill W,
Zeidel M,
Peters LL,
Harding F,
Botstein D,
Korstanje R,
Thaiss C,
Freund A,
Churchill G.
Dietary restriction impacts health and lifespan of genetically diverse mice. Nature. 2024;634(8034):684-92.
Keywords
JMG, Animals, Female, Mice, Adiposity, Body Weight, Caloric Restriction, Fasting, Genetic Variation, Health, Longevity, Resilience, Psychological, Lymphocytes, Erythrocytes
JAX Source
Nature. 2024;634(8034):684-92.
ISSN
1476-4687
PMID
39385029
DOI
https://doi.org/10.1038/s41586-024-08026-3
Grant
We thank the members of the JAX Nathan Shock Center (grant support: NIH P30-038070)
Abstract
Caloric restriction extends healthy lifespan in multiple species. Intermittent fasting, an alternative form of dietary restriction, is potentially more sustainable in humans, but its effectiveness remains largely unexplored. Identifying the most efficacious forms of dietary restriction is key for developing interventions to improve human health and longevity. Here we performed an extensive assessment of graded levels of caloric restriction (20% and 40%) and intermittent fasting (1 and 2 days fasting per week) on the health and survival of 960 genetically diverse female mice. We show that caloric restriction and intermittent fasting both resulted in lifespan extension in proportion to the degree of restriction. Lifespan was heritable and genetics had a larger influence on lifespan than dietary restriction. The strongest trait associations with lifespan included retention of body weight through periods of handling—an indicator of stress resilience, high lymphocyte proportion, low red blood cell distribution width and high adiposity in late life. Health effects differed between interventions and exhibited inconsistent relationships with lifespan extension. 40% caloric restriction had the strongest lifespan extension effect but led to a loss of lean mass and changes in the immune repertoire that could confer susceptibility to infections. Intermittent fasting did not extend the lifespan of mice with high pre-intervention body weight, and two-day intermittent fasting was associated with disruption of erythroid cell populations. Metabolic responses to dietary restriction, including reduced adiposity and lower fasting glucose, were not associated with increased lifespan, suggesting that dietary restriction does more than just counteract the negative effects of obesity. Our findings indicate that improving health and extending lifespan are not synonymous and raise questions about which end points are the most relevant for evaluating aging interventions in preclinical models and clinical trials.
Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.