AP-1 活性是人类体细胞重编程的主要障碍。
AP-1 activity is a major barrier of human somatic cell reprogramming.
机构信息
CAS Key Laboratory of Regenerative Biology, Guangzhou Institutes of Biomedicine and Health, Chinese Academy of Sciences, Guangzhou, 510530, China.
University of Chinese Academy of Sciences, Beijing, 100049, China.
出版信息
Cell Mol Life Sci. 2021 Aug;78(15):5847-5863. doi: 10.1007/s00018-021-03883-x. Epub 2021 Jun 28.
Human induced pluripotent stem cells (iPSCs) technology has been widely applied to cell regeneration and disease modeling. However, most mechanism of somatic reprogramming is studied on mouse system, which is not always generic in human. Consequently, the generation of human iPSCs remains inefficient. Here, we map the chromatin accessibility dynamics during the induction of human iPSCs from urine cells. Comparing to the mouse system, we found that the closing of somatic loci is much slower in human. Moreover, a conserved AP-1 motif is highly enriched among the closed loci. The introduction of AP-1 repressor, JDP2, enhances human reprogramming and facilitates the reactivation of pluripotent genes. However, ESRRB, KDM2B and SALL4, several known pluripotent factors promoting mouse somatic reprogramming fail to enhance human iPSC generation. Mechanistically, we reveal that JDP2 promotes the closing of somatic loci enriching AP-1 motifs to enhance human reprogramming. Furthermore, JDP2 can rescue reprogramming deficiency without MYC or KLF4. These results indicate AP-1 activity is a major barrier to prevent chromatin remodeling during somatic cell reprogramming.
人类诱导多能干细胞(iPSC)技术已广泛应用于细胞再生和疾病建模。然而,体细胞重编程的大多数机制都在小鼠系统中进行研究,在人类中并不总是通用的。因此,人类 iPSC 的产生仍然效率低下。在这里,我们绘制了从尿液细胞诱导人类 iPSC 过程中染色质可及性动态的图谱。与小鼠系统相比,我们发现人类体细胞基因座的关闭速度要慢得多。此外,封闭基因座中富含保守的 AP-1 基序。引入 AP-1 抑制剂 JDP2 可增强人类重编程并促进多能基因的重新激活。然而,几个已知的促进小鼠体细胞重编程的多能因子 ESRRB、KDM2B 和 SALL4 并不能增强人类 iPSC 的产生。从机制上讲,我们揭示了 JDP2 通过促进富含 AP-1 基序的体细胞基因座的关闭来增强人类重编程。此外,JDP2 可以在没有 MYC 或 KLF4 的情况下挽救重编程缺陷。这些结果表明,AP-1 活性是阻止体细胞重编程过程中染色质重塑的主要障碍。
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