Diet-informed metagenomic clocks for aging in the Integrative Longevity Omics Study
Tanya Karagiannis, Anastasia Leshchyk, Meghan Short, Ye Chen, Sarah Bald, Stacy Andersen, Daniel Segrè, Paola Sebastiani

TL;DR
This study creates aging clocks using gut microbiome data and shows that diet influences how the microbiome ages, offering new insights into healthy aging.
Contribution
The paper introduces microbiome-based aging clocks that incorporate diet metrics like caloric intake and a novel Nutrient Variety Index.
Findings
Microbiome-based aging clocks were developed using shotgun metagenomics data from 267 individuals.
Adjusting for caloric intake and Nutrient Variety Index improved clock accuracy, showing diet's role in microbiome aging.
The approach highlights microbial signatures linked to healthy aging and diet-influenced pathways.
Abstract
Aging is a heterogeneous process that unfolds uniquely across individuals and biological systems. Aging clocks, computational models trained on molecular data to estimate biological age, offer a promising framework for investigating aging biology at the individual level. While most clocks rely on epigenetic, transcriptomic, or proteomic data, the human microbiome remains an underutilized source of aging biomarkers despite its central role in host metabolism, immune regulation, and inflammation, all of which are influenced by diet and linked to aging. To explore microbiome-mediated aging, we developed aging clocks using shotgun metagenomics sequencing data from 267 individuals in the Integrative Longevity Omics cohort, including centenarians and their offspring. These clocks estimate biological age based on taxonomic composition across multiple taxonomic levels. To account for dietary…
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Taxonomy
TopicsEpigenetics and DNA Methylation · Gut microbiota and health · Genetics, Aging, and Longevity in Model Organisms
