Partial reprogramming induces a steady decline in epigenetic age before loss of somatic identity

Nelly Olova; Daniel J Simpson; Riccardo E Marioni; Tamir Chandra

doi:10.1111/acel.12877

Partial reprogramming induces a steady decline in epigenetic age before loss of somatic identity

Nelly Olova, Daniel J Simpson, Riccardo E Marioni, Tamir Chandra

Research output: Contribution to journal › Article › peer-review

Abstract

Induced pluripotent stem cells (IPSCs), with their unlimited regenerative capacity, carry the promise for tissue replacement to counter age-related decline. However, attempts to realize in vivo iPSC have invariably resulted in the formation of teratomas. Partial reprogramming in prematurely aged mice has shown promising results in alleviating age-related symptoms without teratoma formation. Does partial reprogramming lead to rejuvenation (i.e., "younger" cells), rather than dedifferentiation, which bears the risk of cancer? Here, we analyse the dynamics of cellular age during human iPSC reprogramming and find that partial reprogramming leads to a reduction in the epigenetic age of cells. We also find that the loss of somatic gene expression and epigenetic age follows different kinetics, suggesting that they can be uncoupled and there could be a safe window where rejuvenation can be achieved with a minimized risk of cancer.

Original language	English
Article number	e12877
Journal	Aging Cell
Volume	18
Issue number	1
Early online date	18 Nov 2018
DOIs	https://doi.org/10.1111/acel.12877
Publication status	Published - 1 Feb 2019

Keywords

aging
aging clock
epigenetic age
IPSC
partial reprogramming
rejuvenation

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2 Finished

Genomics & Microfluidics: taking Cell Biology into the era of Big Data
Ponting, C., Aitman, T. & Bickmore, W.
MRC
1/07/16 → 31/12/18
Project: Research
RA2661 Centre for Cognitive Ageing and Cognitive Epidemiology Phase 2. Main Budget.
Deary, I., Gale, C., Holmes, M., Logie, P., Maclullich, A., Porteous, D., Seckl, J., Starr, J., Wardlaw, J. & Okely, J.
1/09/13 → 31/08/19
Project: Research

Tamir Chandra
- Deanery of Molecular, Genetic and Population Health Sciences - Chancellor's Fellow
- MRC Human Genetics Unit
Person: Academic: Research Active

Cite this

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title = "Partial reprogramming induces a steady decline in epigenetic age before loss of somatic identity",

abstract = "Induced pluripotent stem cells (IPSCs), with their unlimited regenerative capacity, carry the promise for tissue replacement to counter age-related decline. However, attempts to realize in vivo iPSC have invariably resulted in the formation of teratomas. Partial reprogramming in prematurely aged mice has shown promising results in alleviating age-related symptoms without teratoma formation. Does partial reprogramming lead to rejuvenation (i.e., {"}younger{"} cells), rather than dedifferentiation, which bears the risk of cancer? Here, we analyse the dynamics of cellular age during human iPSC reprogramming and find that partial reprogramming leads to a reduction in the epigenetic age of cells. We also find that the loss of somatic gene expression and epigenetic age follows different kinetics, suggesting that they can be uncoupled and there could be a safe window where rejuvenation can be achieved with a minimized risk of cancer.",

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author = "Nelly Olova and Simpson, {Daniel J} and Marioni, {Riccardo E} and Tamir Chandra",

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T1 - Partial reprogramming induces a steady decline in epigenetic age before loss of somatic identity

AU - Olova, Nelly

AU - Simpson, Daniel J

AU - Marioni, Riccardo E

AU - Chandra, Tamir

PY - 2019/2/1

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AB - Induced pluripotent stem cells (IPSCs), with their unlimited regenerative capacity, carry the promise for tissue replacement to counter age-related decline. However, attempts to realize in vivo iPSC have invariably resulted in the formation of teratomas. Partial reprogramming in prematurely aged mice has shown promising results in alleviating age-related symptoms without teratoma formation. Does partial reprogramming lead to rejuvenation (i.e., "younger" cells), rather than dedifferentiation, which bears the risk of cancer? Here, we analyse the dynamics of cellular age during human iPSC reprogramming and find that partial reprogramming leads to a reduction in the epigenetic age of cells. We also find that the loss of somatic gene expression and epigenetic age follows different kinetics, suggesting that they can be uncoupled and there could be a safe window where rejuvenation can be achieved with a minimized risk of cancer.

KW - aging

KW - aging clock

KW - epigenetic age

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KW - rejuvenation

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Partial reprogramming induces a steady decline in epigenetic age before loss of somatic identity

Abstract

Keywords

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Projects

Genomics & Microfluidics: taking Cell Biology into the era of Big Data

RA2661 Centre for Cognitive Ageing and Cognitive Epidemiology Phase 2. Main Budget.

Profiles

Tamir Chandra

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