Telomerase inhibition promotes an initial step of cell differentiation of primate embryonic stem cell

Embryonic stem (ES) cell is well known as a totipotent cell, which is derived from a blastcyst and has potential to differentiate into every kind of somatic cell. ES cell bears self-renewal characteristic as well as differentiation potential. ES cell bears telomerase activity to avoid telomere shortening, which is a characteristic of differentiated somatic cells. As the differentiation of ES cells proceeds, their telomerase activity is losing. However, it has not been convinced whether suppression of the telomerase activity promotes progression of ES cell differentiation. The effect of telomerase inhibitor on the differentiation potential of marmoset ES cell was assessed, counting cells expressing embryonic markers (alkaline phosphatase and TPA-1-60) under existence of a telomerase inhibitor. Telomerase inhibitor showed a promotional effect for the marmoset ES cell differentiation. This result suggests that exogenous inhibition of telomerase activity leads to induction of an early differentiation of primate ES cell.     

Efficient gene transfer into murine embryonic stem cells by nucleofection

Genetic manipulation of embryonic stem (ES) cells is performed by non-viral as well as viral transfection methods. We tested the recently developed nucleofection method delivering plasmid DNA directly into the nucleus for the introduction of a plasmid encoding enhanced green fluorescent protein (EGFP) into murine ES cells. Cell viability decreased from 77% before to 40% 24 h after nucleofection. Transfection effciencies in viable stem cells were between 85% and 96% with high levels of EGFP expression [mean fluorescence intensity (MFI): 630 +/- 90] 24 h after nucleofection. After a two week culture in geneticin (G418) selection medium, nearly 50% of the stem cells were EGFP positive and continued transgene expression (MFIs: 120-240) for a two further weeks. We conclude that nucleofection is an efficient nonviral gene transfer method for the introduction of genes into murine ES cells.     

BCR-ABL induces opposite phenotypes in murine ES cells according to STAT3 activation levels

The mechanisms by which p210-BCR-ABL determines hematopoietic stem cells fate remain poorly understood. To better understand the behavior of BCR-ABL in pluripotent stem cells, we previously developed a murine embryonic stem (ES) cell model transformed by p210-BCR-ABL and reported that BCR-ABL activates STAT3, a major protein involved in ES cells self-renewal, which leads specifically to inhibition of ES cells differentiation. We show here that BCR-ABL either inhibits differentiation or, unexpectedly, induces a rapid commitment to differentiation of murine ES cells, according to the intracellular levels of activated STAT3. We show that inhibition of endogenous STAT3 activation with an inducible STAT3 protein with dominant-negative activity (STAT3F) results in an early, rapid and complete differentiation of BCR-ABL-expressing ES cells, whereas control ES cells retain a more undifferentiated phenotype. This phenomenon could be totally abrogated by PD98059, a specific MEK1 inhibitor, suggesting the involvement of mitogen-activated protein kinase (MAP-Kinase)/ERK1/2 pathway, which was found constitutively phosphorylated in BCR-ABL-expressing cells. In addition, BCR-ABL-expressing ES cells harboring low levels of activated STAT3 committed more rapidly through hematopoietic differentiation, since embryoid bodies (EBs) derived from these cells were able to generate numerous hematopoietic progenitors 2 days early. Moreover, BCR-ABL-expressing ES cells cultured first with low levels of activated STAT3 before EBs derivation displayed a more rapid loss of pluripotency than controls and failed to generate hematopoietic progenitors. This phenomenon was partially abrogated when ES cells were first exposed to PD98059 or to the tyrosine kinase inhibitor imatinib mesylate. From this predictive model, we suggest that variations of the activation levels in BCR-ABL substrates such as STAT3 may represent "instructive" secondary cooperating events involved in the transformation of the leukemic cell phenotype during the course of CML.     

A single point mutation activates the Moloney murine leukemia virus long terminal repeat in embryonal stem cells.

The expression of Moloney murine leukemia virus (Mo-MuLV) and Mo-MuLV-derived vectors is restricted in undifferentiated mouse embryonal carcinoma and embryonal stem (ES) cells. We have previously described the isolation of retroviral mutants with host range properties expanded to embryonal cell lines. One of these mutants, the murine embryonic stem cell virus (MESV), is expressed in ES cell lines. Expression of MESV in these cells relies on DNA sequence motifs within the enhancer region of the viral long terminal repeat (LTR). Here we show that replacement of the Mo-MuLV enhancer region by sequences derived from the MESV LTR results in the activation of the Mo-MuLV LTR in ES cells. The enhancer regions of MESV and Mo-MuLV differ by seven point mutations. Of these, a single point mutation at position -166 is sufficient to activate the Mo-MuLV LTR and to confer enhancer-dependent expression to Mo-MuLV-derived retroviral vectors in ES cells. This point mutation creates a recognition site for a sequence-specific DNA-binding factor present in nuclear extracts of ES cells. This factor was found by functional assays to be the murine equivalent to human Sp1.     

Hybridization of testis-derived stem cells with somatic cells and embryonic stem cells in mice

Somatic cell hybridization is widely used to study the control of gene regulation and the stability of differentiated states. In contrast, the application of this method to germ cells has been limited in part because of an inability to culture germ cells. In this study, we produced germ cell hybrids using germ-line stem (GS) cells and multipotent germ-line stem (mGS) cells. While GS cells are enriched for spermatogonial stem cell (SSC) activity, mGS cells are similar to embryonic stem (ES) cells and originally derived from GS cells. Hybrids were successfully obtained between GS cells and ES cells, between GS cells and mGS cells, and between mGS cells and thymocytes. All exhibited ES cell markers and a behavior similar to ES cells, formed teratomas, and differentiated into somatic cell tissues. However, none of the hybrid cells were able to reconstitute spermatogenesis after microinjection into seminiferous tubules. Analyses of the DNA methylation patterns of imprinted genes also showed that mGS cells do not possess a DNA demethylation ability, which was found in embryonic germ cells derived from primordial germ cells. However, mGS cells reactivated the X chromosome and induced Pou5f1 expression in female thymocytes in a manner similar to ES cells. These data show that mGS cells possess ES-like reprogramming potential, which predominates over-SSC activity.     

High sensitivity of embryonic stem cells to proteasome inhibitors correlates with low expression of heat shock protein and decrease of pluripotent cell marker expression

The ubiquitin-proteasome system is a major proteolytic system for nonlysosomal degradation of cellular proteins. Here, we investigated the response of mouse embryonic stem (ES) cells under proteotoxic stress. Proteasome inhibitors induced expression of heat shock protein 70 (HSP70) in a concentration- and time-dependent manner, and also induced apoptosis of ES cells. Importantly, more apoptotic cells were observed in ES cells compared with other somatic cells. To understand this phenomenon, we further investigated the expression of HSP70 and pluripotent cell markers. HSP70 expression was more significantly increased in somatic cells than in ES cells, and expression levels of pluripotent cell markers such as Oct4 and Nanog were decreased in ES cells. These results suggest that higher sensitivity of ES cells to proteotoxic stress may be related with lower capacity of HSP70 expression and decreased pluripotent cell marker expression, which is essential for the survival of ES cells.