Genetic and environmental contributions to epigenetic aging across adolescence and young adulthood.

IF 4.4 2区医学 Q1 GENETICS & HEREDITY

Clinical Epigenetics Pub Date : 2025-05-07 DOI:10.1186/s13148-025-01880-6

Dmitry V Kuznetsov, Yixuan Liu, Alicia M Schowe, Darina Czamara, Jana Instinske, Charlotte K L Pahnke, Markus M Nöthen, Frank M Spinath, Elisabeth B Binder, Martin Diewald, Andreas J Forstner, Christian Kandler, Bastian Mönkediek

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Abstract

Background: Epigenetic aging estimators commonly track chronological and biological aging, quantifying its accumulation (i.e., epigenetic age acceleration) or speed (i.e., epigenetic aging pace). Their scores reflect a combination of inherent biological programming and the impact of environmental factors, which are suggested to vary at different life stages. The transition from adolescence to adulthood is an important period in this regard, marked by an increasing and, then, stabilizing epigenetic aging variance. Whether this pattern arises from environmental influences or genetic factors is still uncertain. This study delves into understanding the genetic and environmental contributions to variance in epigenetic aging across these developmental stages. Using twin modeling, we analyzed four estimators of epigenetic aging, namely Horvath Acceleration, PedBE Acceleration, GrimAge Acceleration, and DunedinPACE, based on saliva samples collected at two timepoints approximately 2.5 years apart from 976 twins of four birth cohorts (aged about 9.5, 15.5, 21.5, and 27.5 years at first and 12, 18, 24, and 30 years at second measurement occasion).

Results: Half to two-thirds (50-68%) of the differences in epigenetic aging were due to unique environmental factors, indicating the role of life experiences and epigenetic drift, besides measurement error. The remaining variance was explained by genetic (Horvath Acceleration: 24%; GrimAge Acceleration: 32%; DunedinPACE: 47%) and shared environmental factors (Horvath Acceleration: 26%; PedBE Acceleration: 47%). The genetic and shared environmental factors represented the primary sources of stable differences in corresponding epigenetic aging estimators over 2.5 years. Age moderation analyses revealed that the variance due to individually unique environmental sources was smaller in younger than in older cohorts in epigenetic aging estimators trained on chronological age (Horvath Acceleration: 47-49%; PedBE Acceleration: 33-68%). The variance due to genetic contributions, in turn, potentially increased across age groups for epigenetic aging estimators trained in adult samples (Horvath Acceleration: 18-39%; GrimAge Acceleration: 24-43%; DunedinPACE: 42-57%).

Conclusions: Transition to adulthood is a period of the increasing variance in epigenetic aging. Both environmental and genetic factors contribute to this trend. The degree of environmental and genetic contributions can be partially explained by the design of epigenetic aging estimators.

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遗传和环境因素对青春期和青年期表观遗传衰老的影响。

背景：表观遗传衰老估计器通常跟踪时间和生物衰老，量化其积累（即表观遗传年龄加速）或速度（即表观遗传衰老速度）。他们的得分反映了内在生物编程和环境因素影响的结合，这些因素在不同的生命阶段会有所不同。在这方面，从青春期到成年期的过渡是一个重要时期，其特征是表观遗传衰老变异不断增加，然后趋于稳定。这种模式是由环境影响还是遗传因素引起的尚不确定。本研究深入了解遗传和环境对这些发育阶段表观遗传衰老差异的贡献。利用双胞胎模型，我们分析了四种表观遗传衰老的估计方法，即Horvath加速，PedBE加速，GrimAge加速和DunedinPACE，基于四个出生队列（第一次测量年龄约为9.5岁，15.5岁，21.5岁和27.5岁，第二次测量年龄为12岁，18岁，24岁和30岁）的976对双胞胎在两个时间点收集的唾液样本。结果：一半到三分之二（50-68%）的表观遗传衰老差异是由独特的环境因素造成的，这表明除了测量误差外，生活经历和表观遗传漂变也起了作用。剩余的方差由遗传(Horvath加速：24%；图像加速：32%；DunedinPACE: 47%)和共同的环境因素(霍瓦特加速：26%；踏板加速：47%)。遗传因素和共同环境因素是2.5年以上表观遗传衰老估计值稳定差异的主要来源。年龄调节分析显示，在实足年龄训练的表观遗传衰老估计器中，年轻人群体中由于个体独特环境来源造成的差异小于老年人群体(Horvath加速：47-49%；踏板加速：33-68%)。反过来，对于在成人样本中训练的表观遗传衰老估计器，遗传贡献导致的方差可能在不同年龄组中增加(Horvath加速：18-39%；GrimAge加速：24-43%；DunedinPACE: 42 - 57%)。结论：过渡到成年期是表观遗传衰老变异增加的时期。环境和遗传因素都促成了这一趋势。表观遗传老化估计器的设计可以部分解释环境和遗传作用的程度。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Clinical Epigenetics ONCOLOGY-

自引率

5.30%

发文量

150

期刊介绍： Clinical Epigenetics, the official journal of the Clinical Epigenetics Society, is an open access, peer-reviewed journal that encompasses all aspects of epigenetic principles and mechanisms in relation to human disease, diagnosis and therapy. Clinical trials and research in disease model organisms are particularly welcome.