A whole lifespan mouse multi-tissue DNA methylation clock

Meer, Margarita; Podolskiy, Dmitriy I.; Tyshkovskiy, Alexander; Gladyshev, Vadim N.

doi:10.7554/elife.40675

Cited by 148 publications

(221 citation statements)

References 34 publications

(47 reference statements)

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“…Our understanding of the ageing process has historically been hampered by the lack of tools to accurately measure it. In recent years, epigenetic clocks have emerged as powerful biomarkers of the ageing process across mammals [5,6], including humans [7][8][9], mouse [10][11][12][13][14], dogs and wolves [15] and humpback whales [16]. Epigenetic clocks are mathematical models that are trained to predict chronological age using the DNA methylation status of a small number of CpG sites in the genome.…”

Section: Introductionmentioning

confidence: 99%

“…Interestingly, deviations of the epigenetic (biological) age from the expected chronological age (aka epigenetic age acceleration or EAA) have been associated with many conditions in humans, including timeto-death [17,18], HIV infection [19], Down syndrome [20], obesity [21], Werner syndrome [22] and Huntington's disease [23]. In mice, the epigenetic clock is slowed down by dwarfism and calorie restriction [11][12][13][14]24] and is accelerated by ovariectomy and high fat diet [10,13]. Furthermore, in vitro reprogramming of somatic cells into iPSCs reduces epigenetic age to values close to zero both in humans [8] and mice [11,14], which opens the door to potential rejuvenation therapies [25,26] Epigenetic clocks can be understood as a proxy to quantify the changes of the epigenome with age.…”

Section: Introductionmentioning

confidence: 99%

“…In mice, the epigenetic clock is slowed down by dwarfism and calorie restriction [11][12][13][14]24] and is accelerated by ovariectomy and high fat diet [10,13]. Furthermore, in vitro reprogramming of somatic cells into iPSCs reduces epigenetic age to values close to zero both in humans [8] and mice [11,14], which opens the door to potential rejuvenation therapies [25,26] Epigenetic clocks can be understood as a proxy to quantify the changes of the epigenome with age. However, little is known about the molecular mechanisms that determine the rate of these clocks.…”

Section: Introductionmentioning

confidence: 99%

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Screening for genes that accelerate the epigenetic ageing clock in humans reveals a role for the H3K36 methyltransferase NSD1

Martin-Herranz

Aref‐Eshghi

Bonder

et al. 2019

Preprint

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BackgroundEpigenetic clocks are mathematical models that predict the biological age of an individual using DNA methylation data, and which have emerged in the last few years as the most accurate biomarkers of the ageing process. However, little is known about the molecular mechanisms that control the rate of such clocks. Here, we have examined the human epigenetic clock in patients with a variety of developmental disorders, harbouring mutations in proteins of the epigenetic machinery. ResultsUsing the Horvath epigenetic clock, we performed an unbiased screen for epigenetic age acceleration (EAA) in the blood of these patients. We demonstrate that loss-of-function mutations in the H3K36 histone methyltransferase NSD1, which cause Sotos syndrome, substantially accelerate epigenetic ageing. Furthermore, we show that the normal ageing process and Sotos syndrome share methylation changes and the genomic context in which they occur. Finally, we found that the Horvath clock CpG sites are characterised by a higher Shannon methylation entropy when compared with the rest of the genome, which is dramatically decreased in Sotos syndrome patients. ConclusionsThese results suggest that the H3K36 methylation machinery is a key component of the epigenetic maintenance system in humans, which controls the rate of epigenetic ageing, and this role seems to be conserved in model organisms. Our observations provide novel insights into the mechanisms behind the epigenetic ageing clock and we expect will shed light on the different processes that erode the human epigenetic landscape during ageing.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Screening for genes that accelerate the epigenetic ageing clock in humans reveals a role for the H3K36 methyltransferase NSD1

Martin-Herranz

Aref‐Eshghi

Bonder

et al. 2019

Preprint

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“…In humans, these clocks are highly correlated with chronological age, and are able to predict, at the population level, mortality risk and risk of age-related diseases (Horvath and Levine 2015;Horvath et al , 2016Horvath and Raj 2018;Quach et al 2017;Maierhofer et al 2017;Levine et al 2018). Methylation clocks have also been developed for mice, and shown to correlate with chronological age, and respond to lifespan-increasing interventions such as calorie restriction (Meer et al 2018;Petkovich et al 2017;Cole et al 2017;Stubbs et al 2017), but their association with mortality has not yet been explored. However, the major drawback of these mouse clocks is that they require repeated invasive blood collections and time-consuming and expensive data acquisition and analysis procedures.…”

Section: Discussionmentioning

confidence: 99%

Age and life expectancy clocks based on machine learning analysis of mouse frailty

Schultz¹,

Kane

Mitchell

et al. 2019

Preprint

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The identification of genes and interventions that slow or reverse aging is hampered by the lack of non-invasive metrics that can predict life expectancy of pre-clinical models. Frailty Indices (FIs) in mice are composite measures of health that are cost-effective and non-invasive, but whether they can accurately predict health and lifespan is not known. Here, mouse FIs were scored longitudinally until death and machine learning was employed to develop two clocks. A random forest regression was trained on FI components for chronological age to generate the FRIGHT (Frailty Inferred Geriatric Health Timeline) clock, a strong predictor of chronological age. A second model was trained on remaining lifespan to generate the AFRAID (Analysis of Frailty and Death) clock, which accurately predicts life expectancy and the efficacy of a lifespanextending intervention up to a year in advance. Adoption of these clocks should accelerate the identification of novel longevity genes and aging interventions.

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“…Genomic DNA from FACSisolated RGCs was obtained from retinas that are intact or 4-days after axonal injury in the presence or absence of OSK induction and subjected reduced-representation bisulfite sequencing (RRBS). A newly published rDNAme clock 26 provided the best site coverage (70/72 CpG sites) relative to other available mouse clocks 27,28 , and its age estimate remained highly correlated with chronological age of RGCs (Extended Data Fig. 7a and Methods).…”

mentioning

confidence: 94%

Reversal of ageing- and injury-induced vision loss by Tet-dependent epigenetic reprogramming

Krishnan

Brommer

et al. 2019

Preprint

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2Ageing is a degenerative process leading to tissue dysfunction and death. A proposed cause of ageing is the accumulation of epigenetic noise, which disrupts youthful gene expression patterns that are required for cells to function optimally and recover from damage 1-3 .Changes to DNA methylation patterns over time form the basis of an 'ageing clock' 4,5 , but whether old individuals retain information to reset the clock and, if so, whether this would improve tissue function is not known. Of all the tissues in the body, the central nervous system (CNS) is one of the first to lose regenerative capacity 6,7 . Using the eye as a model tissue, we show that expression of Oct4, Sox2, and Klf4 genes (OSK) in mice resets youthful gene expression patterns and the DNA methylation age of retinal ganglion cells, promotes axon regeneration after optic nerve crush injury, and restores vision in a mouse model of glaucoma and in normal old mice. This process, which we call recovery of information via epigenetic reprogramming or REVIVER, requires the DNA demethylases Tet1 and Tet2, indicating that DNA methylation patterns don't just indicate age, they participate in ageing. Thus, old tissues retain a faithful record of youthful epigenetic information that can be accessed for functional age reversal.The metaphor of the epigenetic landscape, first invoked by Waddington to explain embryonic development 8,9 , is increasingly seen as relevant to the other end of life 9. Evidence from yeast and mammals supports an Information Theory of Ageing, in which the loss of epigenetic information disrupts youthful gene expression patterns 1-3 , leading to cellular dysfunction and senescence. 10In mammals, progressive DNA methylation changes serve as an epigenetic clock, but whether they are merely an effect or a driver of ageing is not known 4,5 . In cell culture, the ectopic expression of the four Yamanaka transcription factors, namely Oct4, Sox2, Klf4, and c-Myc (OSKM) 11 , can reprogram somatic cells to become pluripotent stem cells, a process that erases most DNA methylation marks and leads to the loss of cellular identity 4,12 . In vivo, ectopic, transgene-mediated expression of these four genes alleviates progeroid symptoms in a mouse model of Hutchison-Guilford Syndrome, indicating that OSKM might counteract normal ageing 13 . Continual expression of all four factors, however, induces teratomas 14 or causes death within days 13 , ostensibly due to tissue dysplasia 15 .Ageing is generally considered a unidirectional process akin an increase in entropy, butliving systems are open, not closed, and in some cases can fully reset biological age, examples 3 being "immortal" cnidarians and the cloning of animals by nuclear transfer 16 . Having previously found evidence for epigenetic noise as an underlying cause of ageing 2,3 , we wondered whether mammalian cells might retain a faithful copy of epigenetic information from earlier in life, analogous to Shannon's "observer" system in Information Theory, essentially a back-up copy of the original si...

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A whole lifespan mouse multi-tissue DNA methylation clock

Cited by 148 publications

References 34 publications

Screening for genes that accelerate the epigenetic ageing clock in humans reveals a role for the H3K36 methyltransferase NSD1

Screening for genes that accelerate the epigenetic ageing clock in humans reveals a role for the H3K36 methyltransferase NSD1

Age and life expectancy clocks based on machine learning analysis of mouse frailty

Reversal of ageing- and injury-induced vision loss by Tet-dependent epigenetic reprogramming

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