疾病
生物
电池类型
免疫系统
蛋白质组学
细胞
星形胶质细胞
细胞模型
基因型
生物信息学
医学
老化
免疫学
阿尔茨海默病
衰老
年轻人
生物标志物
肌萎缩侧索硬化
全基因组关联研究
慢性阻塞性肺病
微阵列
神经退行性变
阻抑素
神经科学
程序性细胞死亡
生理学
作者
Daisy Yi Ding,Veronica Augustina Bot,Kenneth L. Chen,James E. Groves,Róbert Pálovics,Daisuke Masuda,Amelia Farinas,Hamilton Oh,Viktoria Wagner,Nannan Lu,Carlos Cruchaga,Alina Isakova,Jonathan M. Schott,Tony Wyss‐Coray
出处
期刊:Nature Medicine
[Nature Portfolio]
日期:2026-06-01
卷期号:32 (6): 2060-2072
标识
DOI:10.1038/s41591-026-04446-y
摘要
Aging is asynchronous across cells and organs. Here we tested whether plasma proteomics can be used to analyze cell type-specific aging. From analyses of over 7,000 plasma proteins measured in 60,542 individuals, we developed machine learning models to estimate the biological age of over 40 cell types spanning neuronal, immune, glial, endocrine, epithelial and musculoskeletal origins. We observed that 20-25% of individuals exhibited accelerated aging in a single cell type and 1-3% in 10 or more cell types. Cellular aging signatures were associated with disease status and predicted incident disease and mortality over 15 years of follow-up. Individuals with the APOE4 genotype showed older astrocytes but younger macrophages compared to APOE3 carriers, whereas the APOE2 genotype had inverse associations. Moreover, extreme astrocyte aging tripled the risk of incident Alzheimer's Disease in individuals with two APOE4 alleles, while youthful astrocytes reduced risk. Individuals with extremely aged compared to youthful skeletal myocytes exhibited a 12.7-fold higher risk of developing amyotrophic lateral sclerosis. In individuals who smoked, extreme respiratory epithelial cell aging was associated with a 58% higher lung cancer risk compared to smoking alone. Specific cellular vulnerabilities and cumulative cellular aging burden influenced survival, with youthful immune and neuronal cell types conferring protective effects. Finally, we developed a polycellular aging risk score that stratified mortality risk across cohorts and proteomics platforms. These findings establish a framework for quantifying human physiology at cellular resolution, revealing heterogeneous aging trajectories and their impact on disease susceptibility and resilience.
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