The Impact of the Cardiovascular Component and Somatic Mutations on Ageing

Overview

Journal Aging Cell

Specialties Cell Biology
Geriatrics

Date 2023 Aug 23

PMID 37608601

Authors

Daniel Garger

Martin Meinel

Tamina Dietl

Christina Hillig

Natalie Garzorz-Stark

Kilian Eyerich

Martin Hrabe de Angelis

Stefanie Eyerich

Michael P Menden

Affiliations

Soon will be listed here.

Abstract

Mechanistic insight into ageing may empower prolonging the lifespan of humans; however, a complete understanding of this process is still lacking despite a plethora of ageing theories. In order to address this, we investigated the association of lifespan with eight phenotypic traits, that is, litter size, body mass, female and male sexual maturity, somatic mutation, heart, respiratory, and metabolic rate. In support of the somatic mutation theory, we analysed 15 mammalian species and their whole-genome sequencing deriving somatic mutation rate, which displayed the strongest negative correlation with lifespan. All remaining phenotypic traits showed almost equivalent strong associations across this mammalian cohort, however, resting heart rate explained additional variance in lifespan. Integrating somatic mutation and resting heart rate boosted the prediction of lifespan, thus highlighting that resting heart rate may either directly influence lifespan, or represents an epiphenomenon for additional lower-level mechanisms, for example, metabolic rate, that are associated with lifespan.

Citing Articles

On the causal connection in lifespan correlations and the possible existence of a 'number of life' at molecular level.

Escala A Sci Rep. 2024; 14(1):31707.

PMID: 39738314 PMC: 11685859. DOI: 10.1038/s41598-024-82671-6.

The impact of the cardiovascular component and somatic mutations on ageing.

Garger D, Meinel M, Dietl T, Hillig C, Garzorz-Stark N, Eyerich K Aging Cell. 2023; 22(10):e13957.

PMID: 37608601 PMC: 10577550. DOI: 10.1111/acel.13957.

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