Connections between cross-tissue and intra-tissue biomarkers of aging biology in older adults

Epigenetics communications Pub Date : 2023-10-12 DOI:10.1186/s43682-023-00022-4

R. Waziry, Y. Gu, O. Williams, S. Hägg

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Abstract

Abstract Background Saliva measures are generally more accessible than blood, especially in vulnerable populations. However, connections between aging biology biomarkers in different body tissues remain unknown. Methods The present study included individuals ( N = 2406) who consented for saliva and blood draw in the Health and Retirement Telomere length study in 2008 and the Venous blood study in 2016 who had complete data for both tissues. We assessed biological aging based on telomere length in saliva and DNA methylation and physiology measures in blood. DNA methylation clocks combine information from CpGs to produce the aging measures representative of epigenetic aging in humans. We analyzed DNA methylation clocks proposed by Horvath (353 CpG sites), Hannum (71 CpG sites), Levine or PhenoAge, (513 CpG sites), GrimAge, (epigenetic surrogate markers for select plasma proteins), Horvath skin and blood (391 CpG sites), Lin (99 CpG sites), Weidner (3 CpG sites), and VidalBralo (8 CpG sites). Physiology measures (referred to as phenotypic age) included albumin, creatinine, glucose, [log] C-reactive protein, lymphocyte percent, mean cell volume, red blood cell distribution width, alkaline phosphatase, and white blood cell count. The phenotypic age algorithm is based on parametrization of Gompertz proportional hazard models. Average telomere length was assayed using quantitative PCR (qPCR) by comparing the telomere sequence copy number in each patient’s sample (T) to a single-copy gene copy number (S). The resulting T/S ratio was proportional to telomere length, mean. Within individual, relationships between aging biology measures in blood and saliva and variations according to sex were assessed. Results Saliva-based telomere length showed inverse associations with both physiology-based and DNA methylation-based aging biology biomarkers in blood. Longer saliva-based telomere length was associated with 1 to 4 years slower biological aging based on blood-based biomarkers with the highest magnitude being Weidner ( β = − 3.97, P = 0.005), GrimAge ( β = − 3.33, P < 0.001), and Lin ( β = − 3.45, P = 0.008) biomarkers of DNA methylation. Conclusions There are strong connections between aging biology biomarkers in saliva and blood in older adults. Changes in telomere length vary with changes in DNA methylation and physiology biomarkers of aging biology. We observed variations in the relationship between each body system represented by physiology biomarkers and biological aging, particularly at the DNA methylation level. These observations provide novel opportunities for integration of both blood-based and saliva-based biomarkers in clinical care of vulnerable and clinically difficult to reach populations where either or both tissues would be accessible for clinical monitoring purposes.

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老年人衰老生物学的跨组织和组织内生物标志物之间的联系

唾液检测通常比血液检测更容易获得，特别是在弱势人群中。然而，不同身体组织中衰老生物学生物标志物之间的联系尚不清楚。方法本研究纳入2008年健康与退休端粒长度研究和2016年静脉血研究中同意唾液和血液采集的个体(N = 2406)，这些个体在这两个组织中都有完整的数据。我们根据唾液中的端粒长度和血液中的DNA甲基化和生理测量来评估生物衰老。DNA甲基化时钟结合来自CpGs的信息来产生代表人类表观遗传衰老的衰老措施。我们分析了Horvath(353个CpG位点)、Hannum(71个CpG位点)、Levine或PhenoAge(513个CpG位点)、GrimAge(选择血浆蛋白的表观遗传替代标记)、Horvath皮肤和血液(391个CpG位点)、Lin(99个CpG位点)、Weidner(3个CpG位点)和VidalBralo(8个CpG位点)提出的DNA甲基化时钟。生理指标(称为表型年龄)包括白蛋白、肌酐、葡萄糖、[log] c反应蛋白、淋巴细胞百分比、平均细胞体积、红细胞分布宽度、碱性磷酸酶和白细胞计数。表型年龄算法基于Gompertz比例风险模型的参数化。使用定量PCR (qPCR)通过比较每个患者样本中的端粒序列拷贝数(T)与单拷贝基因拷贝数(S)来测定平均端粒长度。得到的T/S比率与端粒长度(平均值)成正比。在个体内部，评估了血液和唾液中的衰老生物学指标与性别差异之间的关系。结果基于唾液的端粒长度与血液中基于生理和DNA甲基化的衰老生物学标志物呈负相关。基于唾液的端粒长度越长，基于血液的生物标志物的生物衰老速度越慢1至4年，其中幅度最大的是Weidner (β = - 3.97, P = 0.005)， GrimAge (β = - 3.33, P <0.001)和Lin (β = - 3.45, P = 0.008) DNA甲基化生物标志物。结论老年人唾液和血液中的衰老生物学标志物之间存在很强的联系。端粒长度的变化随DNA甲基化和衰老生物学生理生物标志物的变化而变化。我们观察到生理生物标志物代表的每个身体系统与生物衰老之间关系的变化，特别是在DNA甲基化水平上。这些观察结果为在临床护理中整合基于血液和基于唾液的生物标志物提供了新的机会，这些生物标志物在临床护理中是脆弱的，并且临床难以到达的人群，其中一种或两种组织都可以用于临床监测目的。

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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Epigenetics communications

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