Department of Human Genetics, David Geffen School of Medicine, UCLA, Los Angeles, CA 90095, USA.
J Biol Chem. 2010 Jul 2;285(27):21082-91. doi: 10.1074/jbc.M110.125674. Epub 2010 Apr 19.
In defense of deleterious retrotransposition of intracisternal A particle (IAP) elements, IAP loci are heavily methylated and silenced in mouse somatic cells. To determine whether IAP is also repressed in pluripotent stem cells by DNA methylation, we examined IAP expression in demethylated mouse embryonic stem cells (mESCs) and epiblast-derived stem cells. Surprisingly, in demethylated ESC cultures carrying mutations of DNA methyltransferase I (Dnmt1), no IAP transcripts and proteins are detectable in undifferentiated Oct4(+) ESCs. In contrast, approximately 3.6% of IAP-positive cells are detected in Oct4(-) Dnmt1(-/-) cells, suggesting that the previously observed increase in IAP transcripts in the population of Dnmt1(-/-) ESCs could be accounted for by this subset of Oct4(-) Dnmt1(-/-) ESCs undergoing spontaneous differentiation. Consistent with this possibility, a dramatic increase of IAP mRNA (>100-fold) and protein expression was observed in Dnmt1(-/-) ESC cultures upon induction of differentiation through the withdrawal of leukemia-inhibitory factor for 6 or more days. Interestingly, both mRNAs and proteins of IAP can be readily detected in demethylated Oct4(+) epiblast-derived stem cells as well as differentiated mouse embryo fibroblasts, neurons, and glia upon conditional Dnmt1 gene deletion. These data suggest that mESCs are a unique stem cell type possessing a DNA methylation-independent IAP repression mechanism. This methylation-independent mechanism does not involve Dicer-mediated action of microRNAs or RNA interference because IAP expression remains repressed in Dnmt1(-/-); Dicer(-/-) double mutant ESCs. We suggest that mESCs possess a unique DNA methylation-independent mechanism to silence retrotransposons to safeguard genome stability while undergoing rapid cell proliferation for self-renewal.
为了替内源性逆转录转座子(IAP)元件的有害转座行为辩护,IAP 基因座在小鼠体细胞中高度甲基化和沉默。为了确定 IAP 是否也被 DNA 甲基化在多能干细胞中抑制,我们检查了去甲基化的小鼠胚胎干细胞(mESC)和胚外干细胞中的 IAP 表达。令人惊讶的是,在携带 DNA 甲基转移酶 I(Dnmt1)突变的去甲基化 ESC 培养物中,未分化的 Oct4(+) ESC 中无法检测到 IAP 转录本和蛋白质。相比之下,在 Oct4(-) Dnmt1(-/-)细胞中,大约 3.6%的细胞呈 IAP 阳性,这表明先前观察到的 Dnmt1(-/-) ESC 群体中 IAP 转录本的增加可能是由这部分 Oct4(-) Dnmt1(-/-) ESC 自发分化引起的。与这种可能性一致的是,在通过去除白血病抑制因子诱导分化超过 6 天之后,Dnmt1(-/-) ESC 培养物中 IAP mRNA(>100 倍)和蛋白质表达显著增加。有趣的是,在条件性 Dnmt1 基因缺失后,在去甲基化的 Oct4(+)胚外干细胞以及分化的小鼠胚胎成纤维细胞、神经元和神经胶质中,IAP 的 mRNA 和蛋白质都可以很容易地检测到。这些数据表明,mESC 是一种独特的干细胞类型,具有独立于 DNA 甲基化的 IAP 抑制机制。这种不依赖于甲基化的机制不涉及 Dicer 介导的 microRNA 或 RNA 干扰作用,因为 IAP 表达在 Dnmt1(-/-);Dicer(-/-)双突变体 ESC 中仍受到抑制。我们认为,mESC 具有独特的不依赖于 DNA 甲基化的机制来沉默逆转座子,以在快速增殖以维持自我更新的同时保护基因组稳定性。