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Beta-Hydroxybutyrate but not NMN supplementation mimics caloric restriction reducing early mortality in Daphnia

ABSTRACT: NAD+ homeostasis is an important determinant of lifespan and may be a key mechanism of caloric restriction (CR) expansion of lifespan. Ketone bodies such as beta-hydroxybutyrate (BHB) that regulate NAD+ abundance and NAD+ precursors such nicotinamide mononucleotide (NMN), are known to extend life in experimental animals and ameliorate age-related conditions in humans. We tested the hypothesis that chronic BHB and NMN exposure can extend lifespan similarly to the effect of CR treatment in a model organism Daphnia, a freshwater zooplankton crustacean. We also measured fecundity, lipofuscin accumulation, and lipid investments into offspring in Daphnia fed the full diet, full diet with BHB, NMN, and combined treatments, and fed the CR diet (25% of the full diet). We show that BHB exposure, but not NMN exposure, reduces early life mortality in fully fed Daphnia to levels similar to those observed under CR without compromising fecundity. We also observed that in a combined exposure cohort, NMN nearly eliminates the beneficial effect of BHB. None of the treatments affected lipofuscin accumulation, but the NMN and the combined treatment mimicked the effect of CR on neonate size in older females. An RNAseq experiment comparing the two diets and the two exposure treatments showed showed that BHB-treated Daphnia change expression of a variety of genes, including genes with known longevity extending effects, but differential expression of few genes is consistent with the effects of CR and their functionality is not clear.

ORGANISM(S): Daphnia magna

PROVIDER: GSE292526 | GEO | 2025/12/11

REPOSITORIES: GEO

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