Charité - Universitätsmedizin Berlin, corporate member of Freie Universität Berlin, Humboldt-Universität zu Berlin, and Berlin Institute of Health, Lipid Clinic at the Interdisciplinary Metabolism Center, Germany.
Charité - Universitätsmedizin Berlin, BCRT - Berlin Institute of Health Center for Regenerative Therapies, Germany.
J Gerontol A Biol Sci Med Sci. 2020 Oct 15;75(11):2056-2063. doi: 10.1093/gerona/glaa101.
DNA methylation (DNAm) age acceleration, a parameter derived via the epigenetic clock, has recently been suggested as a biomarker of aging. We hypothesized that accelerated biological aging, measured by both this new and the established biomarker of aging, relative leukocyte telomere length (rLTL), are associated with vitamin D deficiency. Moreover, we tested for an association between rLTL/DNAm age acceleration and different clinical assessments for functional capacity, including the Fried frailty score. Cross-sectional data of 1,649 participants of the Berlin Aging Study II was available (~50% female, age: 22-37 and 60-84 years). A seven cytosine-phosphate-guanine clock was estimated to calculate the DNAm age acceleration. rLTL was measured by quantitative real-time polymerase chain reaction (PCR). 25-hydroxyvitamin D (25(OH)D) serum levels <25 nmol/L was defined as vitamin D deficiency and <50 nmol/L as vitamin D insufficiency. Vitamin D-sufficient individuals had a 1.4 years lower mean DNAm age acceleration (p < .05, analysis of variance [ANOVA]) and a 0.11 longer rLTL (p < .001, ANOVA) than vitamin D-deficient participants. Likewise, vitamin D-sufficient participants had lower DNAm age acceleration (β = 1.060, p = .001) and longer rLTL (β = -0.070; p < .001) than vitamin D nonsufficient subjects in covariate-adjusted analysis. Neither DNAm age acceleration nor rLTL were significantly associated with the Fried frailty score or the functional assessments. Only the clock drawing test was associated with DNAm age acceleration (subgroup of older men: β = 1.898, p = .002). Whether the analyzed biomarkers of aging can be used to predict an individual's functional capacity or will be associated with frailty in the advanced course of aging, will be clarified by future longitudinal analyses.
DNA 甲基化(DNAm)年龄加速,这是通过表观遗传钟得出的一个参数,最近被认为是衰老的生物标志物。我们假设,通过新的和已建立的衰老生物标志物——相对白细胞端粒长度(rLTL)来衡量的加速生物学衰老与维生素 D 缺乏有关。此外,我们还测试了 rLTL/DNAm 年龄加速与不同的临床功能能力评估之间的关联,包括弗莱德虚弱评分。柏林老龄化研究 II 的 1649 名参与者的横断面数据可用(约 50%为女性,年龄为 22-37 岁和 60-84 岁)。使用定量实时聚合酶链反应(PCR)来测量 rLTL。估计了一个七胞嘧啶-磷酸-鸟嘌呤时钟来计算 DNAm 年龄加速。25-羟维生素 D(25(OH)D)血清水平 <25 nmol/L 定义为维生素 D 缺乏,<50 nmol/L 为维生素 D 不足。维生素 D 充足的个体的平均 DNAm 年龄加速降低 1.4 岁(p <.05,方差分析 [ANOVA]),rLTL 延长 0.11 个单位(p <.001,ANOVA),而维生素 D 缺乏的参与者。同样,在协变量调整分析中,维生素 D 充足的参与者的 DNAm 年龄加速(β = 1.060,p =.001)和 rLTL(β = -0.070;p <.001)都低于维生素 D 不足的参与者。无论是 DNAm 年龄加速还是 rLTL,都与弗莱德虚弱评分或功能评估无显著关联。只有画钟测验与 DNAm 年龄加速相关(老年男性亚组:β = 1.898,p =.002)。这些衰老的生物标志物是否可以用于预测个体的功能能力,或者在衰老的后期阶段是否与虚弱相关,将通过未来的纵向分析来阐明。
