Nanog基因的功能与调控研究进展

胚胎干细胞的无限增殖能力和亚全能性决定了它在再生医学、新药开发及发育生物学基础研究中具有巨大的应用前景。探索维持胚胎干细胞亚全能性的因子及其网络的调控功能成为胚胎干细胞生物学研究的热点。已研究发现多个与维持胚胎干细胞亚全能性相关的基因如Oct4, Nanog, Sox2等,其中Nanog是2003年5月末发现的一个基因,它对维持胚胎干细胞亚全能性起关键性作用,能够独立于L1F/Stat3维持ICM和胚胎干细胞的亚全能性。几年来,Nanog的生物学功能及其与 Oct4, Sox2等亚全能性维持基因之间的相互作用关系已有较为深入的研究,并发现多个调控Nanog表达的转录因子,从而进一步明晰Nanog与已知调控胚胎发育的信号通路之间的关系。本文在综述Nanog基因的表达特征和功能的基础上、重点探讨Nanog基因表达调控以及Oct4, Sox2等亚全能性维持基因之间的相互作用关系,并对未来的研究趋势予以展望。     

The homeoprotein Nanog is required for maintenance of pluripotency in mouse epiblast and ES cells

Embryonic stem (ES) cells derived from the inner cell mass (ICM) of blastocysts grow infinitely while maintaining pluripotency. Leukemia inhibitory factor (LIF) can maintain self-renewal of mouse ES cells through activation of Stat3. However, LIF/Stat3 is dispensable for maintenance of ICM and human ES cells, suggesting that the pathway is not fundamental for pluripotency. In search of a critical factor(s) that underlies pluripotency in both ICM and ES cells, we performed in silico differential display and identified several genes specifically expressed in mouse ES cells and preimplantation embryos. We found that one of them, encoding the homeoprotein Nanog, was capable of maintaining ES cell self-renewal independently of LIF/Stat3. nanog-deficient ICM failed to generate epiblast and only produced parietal endoderm-like cells. nanog-deficient ES cells lost pluripotency and differentiated into extraembryonic endoderm lineage. These data demonstrate that Nanog is a critical factor underlying pluripotency in both ICM and ES cells.     

维持胚胎干细胞多能性的分子机制

胚胎干细胞（ES细胞）来源于早期发育的胚胎,具有分化为任何细胞类型的多能性,因此具有巨大的基础研究及潜在的应用前景.目前认为ES细胞主要通过一些外源性信号分子的作用及某些重要的内源性转录因子的表达共同起作用来达到其维持多能性的目的.外源性信号分子LIF、BMP4以及Wnt等介导的信号传导通路与内源性转录因子Oct4、Nanog、Sox2、FoxD3等共同起作用来抑制那些促进ES细胞分化的基因表达和激活那些有助于维持ES细胞多能性维持的基因表达,进而形成一个相互调控和依存的基因调控网络共同维持ES细胞的多能性.     

Nanog overcomes reprogramming barriers and induces pluripotency in minimal conditions

Induced pluripotency requires the expression of defined factors and culture conditions that support the self-renewal of embryonic stem (ES) cells. Small molecule inhibition of MAP kinase (MEK) and glycogen synthase kinase 3 (GSK3) with LIF (2i/LIF) provides an optimal culture environment for mouse ES cells and promotes transition to naive pluripotency in partially reprogrammed (pre-iPS) cells. Here we show that 2i/LIF treatment in clonal lines of pre-iPS cells results in the activation of endogenous Nanog and rapid downregulation of retroviral Oct4 expression. Nanog enables somatic cell reprogramming in serum-free medium supplemented with LIF, a culture condition which does not support induced pluripotency or the self-renewal of ES cells, and is sufficient to reprogram epiblast-derived stem cells to naive pluripotency in serum-free medium alone. Nanog also enhances reprogramming in cooperation with kinase inhibition or 5-aza-cytidine, a small molecule inhibitor of DNA methylation. These results highlight the capacity of Nanog to overcome multiple barriers to reprogramming and reveal a synergy between Nanog and chemical inhibitors that promote reprogramming. We conclude that Nanog induces pluripotency in minimal conditions. This provides a strategy for imposing naive pluripotency in mammalian cells independently of species-specific culture requirements.     

Synergistic action of Wnt and LIF in maintaining pluripotency of mouse ES cells

Leukaemia inhibitory factor (LIF) was the first soluble factor identified as having potential to maintain the pluripotency of mouse embryonic stem (ES) cells. Recently, a second factor, Wnt, with similar activity was found. However, the relationship between these completely different signals mediating the overlapping functions is still unclear. Here, we report that the conditioned medium of L cells expressing Wnt3a maintains ES cells in the undifferentiated state in feeder-free culture, followed by expression of stem cell markers and their ability to generate germline chimaeras. However, although the activity of this conditioned medium is dependent on Wnt3a, recombinant Wnt3a protein cannot maintain ES cells in the undifferentiated state. As supplementation with Wnt3a to the sub-threshold level of LIF alone was not sufficient to maintain ES self-renewal, the results of maintenance of the undifferentiated state indicated the synergistic action of Wnt and LIF. Induction of constitutively activated beta-catenin alone is unable to maintain ES self-renewal but shows a synergistic effect with LIF. These observations indicate that the Wnt signal mediated by the canonical pathway is not sufficient but enhances the effect of LIF to maintain self-renewal of mouse ES cells.     

New insights into the mechanisms of embryonic stem cell self-renewal under hypoxia: a multifactorial analysis approach

Previous reports have shown that culturing mouse embryonic stem (mES) cells at different oxygen tensions originated different cell proliferation patterns and commitment stages depending on which signaling pathways are activated or inhibited to support the pluripotency state. Herein we provide new insights into the mechanisms by which oxygen is influencing mES cell self-renewal and pluripotency. A multifactorial approach was developed to rationally evaluate the singular and interactive control of MEK/ERK pathway, GSK-3 inhibition, and LIF/STAT3 signaling at physiological and non-physiological oxygen tensions. Collectively, our methodology revealed a significant role of GSK-3-mediated signaling towards maintenance of mES cell pluripotency at lower O(2) tensions. Given the central role of this signaling pathway, future studies will need to focus on the downstream mechanisms involved in ES cell self-renewal under such conditions, and ultimately how these findings impact human models of pluripotency.     

Design of the artificial acellular feeder layer for the efficient propagation of mouse embryonic stem cells

Embryonic stem (ES) cells are pluripotent-undifferentiated cells that have a great interest for the investigation of developmental biology. Murine ES cells maintain their pluripotency by the supplementation of the leukemia inhibitory factor (LIF). LIF is reported to act as a matrix-anchored form, and immobilized cytokines are useful to sustain their signaling on target cells. In this study, we used the immobilizable fusion protein composed of LIF and IgG-Fc region, which was used as a model of the matrix-anchored form of LIF to establish a novel system for ES cell culture and to investigate the effect of immobilized LIF on maintenance of ES cell pluripotency. Mouse ES cells maintained their undifferentiated state on the surface coated with LIF-Fc. Furthermore, when cultured on the co-immobilized surface with LIF-Fc and E-cadherin-Fc, mouse ES cells showed characteristic scattering morphologies without colony formation, and they could maintain their undifferentiated state and pluripotency without additional LIF supplementation. The activation of LIF signaling was sustained on the co-immobilized surface. These results indicate that immobilized LIF and E-cadherin can maintain mouse ES cells efficiently and that the immobilizable LIF-Fc fusion protein is useful for the investigation of signaling pathways of an immobilized form of LIF in the maintenance of ES cell pluripotency.