Genomic integrity of ground-state pluripotency

Publication date

2018-12

Authors

Jafari, Narges
Giehr, Pascal
Hesaraki, Mahdi
Baas, Roy
de Graaf, PetraORCID 0000-0002-3183-8901ISNI 0000000392892044
Timmers, MarcISNI 0000000389187205
Walter, Jörn
Baharvand, Hossein
Totonchi, Mehdi

Editors

Advisors

Supervisors

Document Type

Article

Collections

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License

taverne

Abstract

Pluripotent cells appear to be in a transient state during early development. These cells have the capability to transition into embryonic stem cells (ESCs). It has been reported that mouse pluripotent cells cultivated in chemically defined media sustain the ground state of pluripotency. Because the epigenetic pattern of pluripotent cells reflects their environment, culture under different conditions causes epigenetic changes, which could lead to genomic instability. This study focused on the DNA methylation pattern of repetitive elements (REs) and their activation levels under two ground-state conditions and assessed the genomic integrity of ESCs. We measured the methylation and expression level of REs in different media. The results indicated that although the ground-state conditions show higher REs activity, they did not lead to DNA damage; therefore, the level of genomic instability is lower under the ground-state compared with the conventional condition. Our results indicated that when choosing an optimum condition, different features of the condition must be considered to have epigenetically and genomically stable stem cells.

Keywords

DNA methylation, embryonic stem cells (ESCs), genomic instability, ground state of pluripotency, repetitive elements (REs), Taverne, Biochemistry, Molecular Biology, Cell Biology

Citation

Jafari, N, Giehr, P, Hesaraki, M, Baas, R, de Graaf, P, Timmers, H T M, Walter, J, Baharvand, H & Totonchi, M 2018, 'Genomic integrity of ground-state pluripotency', Journal of Cellular Biochemistry, vol. 119, no. 12, pp. 9781-9789. https://doi.org/10.1002/jcb.27296