DNA Repair and Replication Links to Pluripotency and Differentiation Capacity of Pig IPS Cells

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2017 Mar 3

PMID 28253351

Citations 5

Authors

Kai Liu

Jian Mao

Lipu Song

Anran Fan

Sheng Zhang

Jianyu Wang

Nana Fan

Na Liu

Xiaoying Ye

Haifeng Fu

Zhongcheng Zhou

Yong Wang

Hong Wei

Zhonghua Liu

Ziyi Li

Liangxue Lai

Xumin Wang

Lin Liu

Affiliations

Soon will be listed here.

Abstract

Pigs are proposed to be suitable large animal models for test of the efficacy and safety of induced pluripotent stem cells (iPSCs) for stem cell therapy, but authentic pig ES/iPS cell lines with germline competence are rarely produced. The pathways or signaling underlying the defective competent pig iPSCs remain poorly understood. By improving induction conditions using various small chemicals, we generated pig iPSCs that exhibited high pluripotency and differentiation capacity that can contribute to chimeras. However, their potency was reduced with increasing passages by teratoma formation test, and correlated with declined expression levels of Rex1, an important marker for naïve state. By RNA-sequencing analysis, genes related to WNT signaling were upregulated and MAPK signaling and TGFβ pathways downregulated in pig iPSCs compared to fibroblasts, but they were abnormally expressed during passages. Notably, pathways involving in DNA repair and replication were upregulated at early passage, but downregulated in iPSCs during prolonged passage in cluster with fibroblasts. Our data suggests that reduced DNA repair and replication capacity links to the instability of pig iPSCs. Targeting these pathways may facilitate generation of truly pluripotent pig iPSCs, with implication in translational studies.

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