The molecular mechanism of embryonic stem cell pluripotency maintenance

In vitro cultured embryonic stem （ES） cells are derived from the inner cell mass （ICM） of pre-implantation embryos, and are capable of giving rise to all cell and tissue types of the three germ layers upon being injected back into blastocysts. These ceils are therefore said to possess pluripotency that can be maintained infinitely in culture under optimal conditions. Such pluripotency maintenance is believed to be due to the symmetrical cleavage of the cells in an undifferentiated state. The pluripotency of ES cells is the basis for their various practical and potential applications. ES cells can be used as donor cells to generate knockout or transgenic animals, as in vitro models of mammalian development, and as cell resources for cell therapy in regenerative medicine. The further success in these applications, particularly in the last two, is dependent on the establishment of a culture system with components in the medium clearly defined and the subsequent procedures for controlled differentiation of the cells into specific lineages. In turn, elucidating the molecular mechanism for pluripotency maintenance of ES cells is the prerequisite. This paper summarizes the recent progresses in this area, focusing mainly on the LIF/STAT3, BMPs/Smads, canonical Wnt, TGFβ/activin/nodal, PI3K and FGF signaling pathways and the genes such as oct4, nanog that are crucial in ES cell pluripotency maintenance. The regulatory systems of pluripotency maintenance in both mouse and human ES cells are also discussed. We believe that the cross-talkings between these signaling pathways, as well as the regulatory system underlying pluripotency maintenance will be the main focus in the area of ES cell researches in the future.     

Effects of STAT3 antisense RNA on IL-6-induced differentiation and growth arrest of Ml leukemia cells

To investigate the biological roles of STAT3 in the regulation of growth and differentiation of leukemia cells, we modified a murine myeloid leukemia cell line Ml with STAT3 antisense RNA. The effects of STAT3 antisense RNA on the growth arrest and terminal differentiation of Ml cells induced by interleukin 6 (IL-6) were determined. It was found that STAT3 antisense RNA blocked the activation of STAT3, and reduced the growth arrest and terminal differentiation of IL-6-induced Ml leukemia cells. These results indicate that STAT3 activation is a necessary process for IL-6-induced growth arrest of Ml cells and for the differentiation of Ml cells into macrophage.     

Differentiation of human embryonic stem cells along a hepatocyte lineage and its application in liver regeneration

Hepatocyte transplantation and bioarUficial liver （BAL） as alternatives to liver transplantation offer the possibility of effective treatment for many inherited and acquired hepatic disorders. Unfortunately, the limited availability of donated livers and the variability of their derived hepatocytes make it difficult to obtain enough viable human hepatocytes for the hepatocyte-based therapies. Embryonic stem cells （ESCs）, which could be isolated directly from the blastocyst inner cell mass, have permanent self-renewal capability and developmental pluripotency and therefore might be an ideal cell source in the treatment of hepatic discords. However, differentiation of hESCs into hepatocytes with significant numbers remains a challenge. This review updates our current understanding of differentiation of ESCs into hepatic lineage cells, their future therapeutic uses and problems in liver regeneration.     

Electroporation Transfection as an Effective Tool to Trace Transplanted NSCs in Adult Central Nervous System

Neural stem cells, which are clonogenic cells with self-renewal and multilineage differentiation properties, are currently considered as powerful candidates for cell replacement therapy in neurodegenerative disorders such as Parkinson‘s disease. A key issue is whether stem cells can survive, migrate and differentiate following transplantation into the adult central nervous system. This research shows that enhanced green fluorescent protein (EGFP) plasmid electreporation transfected neural stem cells can functionally differentiate in vitro and that most of the EGFP-positive cells can survive and migrate towards the damaged areas when transplanted into the brain of a Parkinson‘s disease model rat. The results suggest an effective and maneuverable tracing tool to detect whether transplanted neural stem and progenitor cells function in the adult brain in vivo.     

Generation of tetraploid complementation mice from embryonic stem cells cultured with chemical defined medium

Mouse embryonic stem cells(mESCs)derived from inner cell mass(ICM)of pre-implantation embryos,can maintain undifferentiated state when cultured in N2B27 medium supplemented with GSK3inhibitor CHIR99021 and MEK inhibitor PD0325901(‘‘2i’’)and leukemia inhibitor factor(LIF).Compare to conventional culture medium,all components of this medium are defined.With the N2B27 medium,‘‘2i’’and LIF,mESCs can contribute to the germline of the chimeric embryos,however,whether the‘‘all-ES cells’’mice can been generated by tetraploid complementation is unclear yet,while the tetraploid complementation serve as a golden standard to assess the pluripotency of ES cells.Here,our study showed that mESCs derived and cultured with the N2B27 complete medium could generate fertile mice by tetraploid complementation.In addition,the survival rate of tetraploid complementation mice produced by inbred mES cell lines is higher than the conventional culture condition,and increased the percentage of Oct4 positive cells contrast to conventional medium either.Therefore,the N2B27 medium supplemented with‘‘2i’’and LIF is an alternative choice forthe derivation and long-term culture of mouse embryonic stem cells.     

Metformin targets liver tumor-initiating cells through the PI3K/Akt/mTOR survival pathway

Liver tumor-initiating cells （T-ICs） are thought to be inherently resistant to the cytotoxic effects of chemo- therapy, and can self-renewal and maintain tumor-initiating potential. Therefore, effective anticancer research strategies should target the unique properties of T-ICs. In this study, we found that metformin, a first-line drug of choice for the treatment of type 2 diabetes, inhibited liver T-ICs both in vivo and in vitro. Metformin inhibited the formation of hepato- spheres and epithelial-specific antigen-positive （ESA, CD133＋） cell colonies by hepatocellular carcinoma （HCC） cell lines. Metformin also downregulated the expression of several T-IC-related genes which are involved in the signal- ing pathways, governing the self-renewal, proliferation and differentiation of T-ICs. Furthermore, the targeting of liver T-ICs by metformin was PI-3-kinase-Akt-mTOR （PI3K/Akt/ mTOR）-pathway dependent. The PI3K/Akt/mTOR inhibitorLY294002 and rapamycin abolished the inhibitory effect of metformin on CD133＋ cells, and the PI3K/Akt/mTOR stimulator EGF promoted the inhibitory effect of mefformin on CD 133＋ cells. Metformin also dramatically decreased the tumor volume and number of CD133 expressing tumor cells in a xenograft mouse model. Mefformin exerted a synergistic effect with cisplatin to target both T-ICs and non-T-ICs, and resulted in the smallest tumor volume and lowest number of CD133 expressing tumor cells. This study indicates that the antidiabetic drug metformin could potentially be used in combination therapy with chemotherapeutic agents to improve the treatment of liver cancer.     

Cytokinin signal transduction： Known simplicity and unknown complexity

Cytokinin plays a critical role in plant growth and development by regulating cell divisions and cell differentiation. Recent studies suggest that cytokinin signaling is presumably mediated by a two-component system analogous to those found in bacteria and fungi, which transduces an external signal via a phosphorelay from the plasma membrane-anchored receptors to downstream effectors and regulators. Moreover, cytokinin signaling is highly interactive with other pathways, and many components of the pathway appear to be functionally redundant. Proper address of these questions will be crucial for our further understanding on this important network.     

Forced expression of theOct-4 gene influences differentiation of embryonic stem cells

By transfecting an Oct-4 expression plasmid into embryonic stem cells (ES cells), the ES-O cell line was constructed, which sustained the expression of Oct-4 gene when induced by retinoic acid. Forced expression of Oct-4 gene could not sustain the stem property of ES-O cells without the differentiation inhibiting factor LIF, but if LIF exists, forced expression of Oct-4 gene could enhance the ability to sustain the undifferentiation state and inhibit cell differentiation induced by retinoic acid. It was indicated that Oct-4 must cooperate with LIF to sustain the undifferentiation state of ES cells. During the cell differentiation, ES-O cells tend to differentiate into neural cells, suggesting that forced expression of Oct-4 gene may be in relation with the differentiation of neuroderm.     

Control of ground-state pluripotency by allelic regulation of Nanog

Pluripotency is established through genome-wide reprogramming during mammalian pre-implantation development, resulting in the formation of the naive epiblast. Reprogramming involves both the resetting of epigenetic marks and the activation of pluripotent-cell-specific genes such as Nanog and Oct4 (also known as Pou5f1). The tight regulation of these genes is crucial for reprogramming, but the mechanisms that regulate their expression in vivo have not been uncovered. Here we show that Nanog--but not Oct4--is monoallelically expressed in early pre-implantation embryos. Nanog then undergoes a progressive switch to biallelic expression during the transition towards ground-state pluripotency in the naive epiblast of the late blastocyst. Embryonic stem (ES) cells grown in leukaemia inhibitory factor (LIF) and serum express Nanog mainly monoallelically and show asynchronous replication of the Nanog locus, a feature of monoallelically expressed genes, but ES cells activate both alleles when cultured under 2i conditions, which mimic the pluripotent ground state in vitro. Live-cell imaging with reporter ES cells confirmed the allelic expression of Nanog and revealed allelic switching. The allelic expression of Nanog is regulated through the fibroblast growth factor-extracellular signal-regulated kinase signalling pathway, and it is accompanied by chromatin changes at the proximal promoter but occurs independently of DNA methylation. Nanog-heterozygous blastocysts have fewer inner-cell-mass derivatives and delayed primitive endoderm formation, indicating a role for the biallelic expression of Nanog in the timely maturation of the inner cell mass into a fully reprogrammed pluripotent epiblast. We suggest that the tight regulation of Nanog dose at the chromosome level is necessary for the acquisition of ground-state pluripotency during development. Our data highlight an unexpected role for allelic expression in controlling the dose of pluripotency factors in vivo, adding an extra level to the regulation of reprogramming.