Aging of blood can be tracked by DNA methylation changes at just three CpG sites

Weidner, Carola I.; Lin, Qiong; Koch, Carmen M.; Eisele, Lewin; Beier, Fabian; Ziegler, Patrick; Bauerschlag, Dirk; Jöckel, Karl‐Heinz; Erbel, Raimund; Mühleisen, Thomas W.; Zenke, Martin; Brümmendorf, Tim H.; Wagner, Wolfgang

doi:10.1186/gb-2014-15-2-r24

Cited by 745 publications

(896 citation statements)

References 59 publications

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“…Studies that examined this period of human development have reported that DNA methylation levels increase rapidly and then stabilize by adulthood in both brain and blood (Alisch et al ., 2012; Lister et al ., 2013). From adulthood to advanced age, overall levels of DNA methylation remain stable in blood, while interindividual variability increases over that time (Talens et al ., 2012; Weidner et al ., 2014). Postadulthood, many studies have found a mean decrease in blood DNA methylation with increasing age (Bjornsson et al ., 2004; Boks et al ., 2009; Heyn et al ., 2012; Horvath et al ., 2012; Hannum et al ., 2013; Johansson et al ., 2013; Florath et al ., 2014; Weidner et al ., 2014).…”

Section: Dna Methylation Dynamics During Agingmentioning

confidence: 99%

“…From adulthood to advanced age, overall levels of DNA methylation remain stable in blood, while interindividual variability increases over that time (Talens et al ., 2012; Weidner et al ., 2014). Postadulthood, many studies have found a mean decrease in blood DNA methylation with increasing age (Bjornsson et al ., 2004; Boks et al ., 2009; Heyn et al ., 2012; Horvath et al ., 2012; Hannum et al ., 2013; Johansson et al ., 2013; Florath et al ., 2014; Weidner et al ., 2014). These changes are less likely to occur in promoters and more likely to be observed in enhancers (Johansson et al ., 2013).…”

Section: Dna Methylation Dynamics During Agingmentioning

confidence: 99%

“…These changes are less likely to occur in promoters and more likely to be observed in enhancers (Johansson et al ., 2013). Regions that gain DNA methylation with age are enriched for CpG islands, while nonislands tend to lose DNA methylation with age (Rakyan et al ., 2010; Heyn et al ., 2012; Horvath et al ., 2012; Florath et al ., 2014; Weidner et al ., 2014). …”

Section: Dna Methylation Dynamics During Agingmentioning

confidence: 99%

“…As most CpGs are located outside of CpG islands and are highly methylated, this translates to an overall loss of DNA methylation in later life as well as a tendency for DNA methylation levels to shift toward the mean with increased age (Saxonov et al ., 2006; Weber et al ., 2007; Illingworth & Bird, 2009; Hannum et al ., 2013; Teschendorff et al ., 2013; Weidner et al ., 2014). …”

Section: Dna Methylation Dynamics During Agingmentioning

confidence: 99%

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DNA methylation and healthy human aging

2015

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SummaryThe process of aging results in a host of changes at the cellular and molecular levels, which include senescence, telomere shortening, and changes in gene expression. Epigenetic patterns also change over the lifespan, suggesting that epigenetic changes may constitute an important component of the aging process. The epigenetic mark that has been most highly studied is DNA methylation, the presence of methyl groups at CpG dinucleotides. These dinucleotides are often located near gene promoters and associate with gene expression levels. Early studies indicated that global levels of DNA methylation increase over the first few years of life and then decrease beginning in late adulthood. Recently, with the advent of microarray and next‐generation sequencing technologies, increases in variability of DNA methylation with age have been observed, and a number of site‐specific patterns have been identified. It has also been shown that certain CpG sites are highly associated with age, to the extent that prediction models using a small number of these sites can accurately predict the chronological age of the donor. Together, these observations point to the existence of two phenomena that both contribute to age‐related DNA methylation changes: epigenetic drift and the epigenetic clock. In this review, we focus on healthy human aging throughout the lifetime and discuss the dynamics of DNA methylation as well as how interactions between the genome, environment, and the epigenome influence aging rates. We also discuss the impact of determining ‘epigenetic age’ for human health and outline some important caveats to existing and future studies.

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Section: Dna Methylation Dynamics During Agingmentioning

confidence: 99%

Section: Dna Methylation Dynamics During Agingmentioning

confidence: 99%

Section: Dna Methylation Dynamics During Agingmentioning

confidence: 99%

Section: Dna Methylation Dynamics During Agingmentioning

confidence: 99%

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DNA methylation and healthy human aging

2015

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“…While the key features of epigenetic drift remain to be defined, several observations have been made that characterize age‐related methylation changes across human tissues. These include the hypermethylation of stem cell genes (Rakyan et al ., 2010; Teschendorff et al ., 2010), a general linear correlation between the methylation level of certain CpGs and the chronological age (Hannum et al ., 2013; Horvath, 2013; Weidner et al ., 2014), and the hypermethylation of CpG islands (Yuan et al ., 2015). The molecular and phenotypic consequences of these alterations remain a topic of active research.…”

Section: Introductionmentioning

confidence: 99%

Reduced DNA methylation patterning and transcriptional connectivity define human skin aging

et al. 2016

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SummaryEpigenetic changes represent an attractive mechanism for understanding the phenotypic changes associated with human aging. Age‐related changes in DNA methylation at the genome scale have been termed ‘epigenetic drift’, but the defining features of this phenomenon remain to be established. Human epidermis represents an excellent model for understanding age‐related epigenetic changes because of its substantial cell‐type homogeneity and its well‐known age‐related phenotype. We have now generated and analyzed the currently largest set of human epidermis methylomes (N = 108) using array‐based profiling of 450 000 methylation marks in various age groups. Data analysis confirmed that age‐related methylation differences are locally restricted and characterized by relatively small effect sizes. Nevertheless, methylation data could be used to predict the chronological age of sample donors with high accuracy. We also identified discontinuous methylation changes as a novel feature of the aging methylome. Finally, our analysis uncovered an age‐related erosion of DNA methylation patterns that is characterized by a reduced dynamic range and increased heterogeneity of global methylation patterns. These changes in methylation variability were accompanied by a reduced connectivity of transcriptional networks. Our findings thus define the loss of epigenetic regulatory fidelity as a key feature of the aging epigenome.

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