Fiorito Giovanni, Tosti Valeria, Polidoro Silvia, Bertozzi Beatrice, Veronese Nicola, Cava Edda, Spelta Francesco, Piccio Laura, Early Dayna S, Raftery Daniel, Vineis Paolo, Fontana Luigi
Clinical Bioinformatics Unit, IRCCS Istituto Giannina Gaslini, Genoa, Italy.
Department of Medicine, Washington University School of Medicine, St. Louis, Missouri, USA.
Aging Cell. 2025 Apr;24(4):e14442. doi: 10.1111/acel.14442. Epub 2024 Dec 18.
Calorie restriction (CR) and physical exercise (EX) are well-established interventions known to extend health span and lifespan in animal models. However, their impact on human biological aging remains unclear. With recent advances in omics technologies and biological age (BioAge) metrics, it is now possible to assess the impact of these lifestyle interventions without the need for long-term follow-up. This study compared BioAge biomarkers in 41 middle-aged and older adult long-term CR practitioners, 41 age- and sex-matched endurance athletes (EX), and 35 sedentary controls consuming Western diets (WD), through PhenoAge: a composite score derived from nine blood-biomarkers. Additionally, a subset of participants (12 CR, 11 EX, and 12 WD) underwent multi-omic profiling, including DNA methylation and RNAseq of colon mucosa, blood metabolomics, and stool metagenomics. A group of six young WD subjects (yWD) served as a reference for BioAge calculation using Mahalanobis distance across six omic layers. The results demonstrated consistently lower BioAge biomarkers in both CR and EX groups compared to WD controls across all layers. CR participants exhibited lower BioAge in gut microbiome and blood-derived omics, while EX participants had lower BioAge in colon mucosa-derived epigenetic and transcriptomic markers, suggesting potential tissue-specific effects. Multi-omic pathway enrichment analyses suggested both shared and intervention-specific mechanisms, including oxidative stress and basal transcription as common pathways, with ether lipid metabolism uniquely enriched in CR. Despite limitations due to sample size, these findings contribute to the broader understanding of the potential anti-aging effects of CR and EX, offering promising directions for further research.
热量限制(CR)和体育锻炼(EX)是公认的干预措施,已知可延长动物模型的健康寿命和寿命。然而,它们对人类生物衰老的影响仍不清楚。随着组学技术和生物年龄(BioAge)指标的最新进展,现在有可能在无需长期随访的情况下评估这些生活方式干预的影响。本研究通过PhenoAge(一种由九种血液生物标志物得出的综合评分)比较了41名中年及老年长期热量限制实践者、41名年龄和性别匹配的耐力运动员(EX)以及35名食用西方饮食(WD)的久坐不动对照组的生物年龄生物标志物。此外,一部分参与者(12名CR、11名EX和12名WD)接受了多组学分析,包括结肠黏膜的DNA甲基化和RNA测序、血液代谢组学和粪便宏基因组学。一组六名年轻的WD受试者(yWD)作为跨六个组学层面使用马氏距离计算生物年龄的参考。结果表明,与WD对照组相比,CR组和EX组在所有层面的生物年龄生物标志物均持续较低。CR参与者在肠道微生物群和血液来源的组学中表现出较低的生物年龄,而EX参与者在结肠黏膜来源的表观遗传和转录组标志物中生物年龄较低,表明存在潜在的组织特异性效应。多组学通路富集分析表明存在共同机制和干预特异性机制,包括氧化应激和基础转录作为共同通路,醚脂代谢在CR中独特富集。尽管由于样本量存在局限性,但这些发现有助于更广泛地理解CR和EX的潜在抗衰老作用,为进一步研究提供了有前景的方向。
