Shigeo Saito

Isolation of embryonic stem-like cells from equine blastocysts and their differentiation in vitro1

Embryonic stem (ES) cells are pluripotent cells with the potential capacity to generate any type of cell. We describe here the isolation of pluripotent ES‐like cells from equine blastocysts that have been frozen and thawed. Our two lines of ES‐like cells (E‐1 and E‐2) appear to maintain a normal diploid karyotype indefinitely in culture in vitro and to express markers that are characteristic of ES cells from mice, namely, alkaline phosphatase, stage‐specific embryonic antigen‐1, STAT‐3 and Oct 4. After culture of equine ES‐like cells in vitro for more than 17 passages, some ES‐like cells differentiated to neural precursor cells in the presence of basic fibroblast growth factor (bFGF), epidermal growth factor and platelet‐derived growth factor. We also developed a protocol that resulted in the differentiation of ES‐like cells in vitro to hematopoietic and endothelial cell lineages in response to bFGF, stem cell factor and oncostatin M. Our observations set the stage for future developments that may allow the use of equine ES‐like cells for the treatment of neurological and hematopoietic disorders.

Generation of cloned calves and transgenic chimeric embryos from bovine embryonic stem-like cells.

Bovine embryonic stem-like cells (ES-like cells) appear to maintain a normal diploid karyotype indefinitely during culture in vitro and to express marker proteins that are characteristic of ES cells from mice, namely, alkaline phosphatase (AP), stage-specific embryonic antigen-1 (SSEA-1), STAT-3, and Oct 4. After proliferation of undifferentiated ES-like cells in vitro, some bovine ES-like cells differentiated to neural precursor cells, which were cultured in the presence of basic fibroblast growth factor (bFGF), epidermal growth factor (EGF), and platelet-derived growth factor (PDGF). In addition, calves were successfully cloned using ES-like cells and the frequency of term pregnancies for blastocysts derived from ES-like cells was higher than those of early pregnancies and maintained pregnancies after nuclear transplantation (NT) with bovine somatic cells. Successful cloning from bovine ES-like cells should allow the introduction into cattle of specific genetic characteristics of biomedical and/or agricultural importance.

Establishment and Characterization of a Pluripotent Stem Cell line Derived from Human Amniotic Membranes and Initiation of Germ Layers in vitro

OBJECTIVES: Pluripotent stem cells are proposed to be used in regenerative therapy and may exist in the human amniotic membrane. The present article is aimed at establishing a pluripotent stem cell line from human placenta. METHODS: HAM-1 (stem cell line derived from human amniotic membranes) was established by the colonial cloning technique using α MEM culture medium containing long/ml of EGF, 10ng/ml of hLIF and 10% fetal bovine serum. RESULTS: HAM-1 cells appeared to maintain a normal karyotype indefinitely in vitro and expressed markers characteristic of stem cells from mice and human, namely alkaline phosphatase. Also, these cells contributed to the formation of chimeric mouse embryoid bodies and gave rise to cells of all germ layers in vitro. CONCLUSIONS: This study demonstrates that human amniotic membranes derived stem cells have a wide developmental capability and might be utilized to regenerate different types of cells or tissues for transplantation therapy.

Animal Embryonic Stem (ES) Cells: Self‐renewal, Pluripotency, Transgenesis and Nuclear Transfer

Mouse embryonic stem (ES) cells can be maintained indefinitely in the presence of leukemia inhibitory factor (LIF) and they express markers of self-renewal and pluripotency, which include the transcription factor Oct 4, STAT-3, stage-specific embryonic antigen (SEA)-1, and alkaline phosphatase (AP). Upon removal of LIF, from the culture medium they cease to express markers such as Oct 4, rapidly losing the capacity for self-renewal and differentiating into a variety of cell types. Gene targeting is feasible in murine Es cells because these cells can be maintained in an undifferentiated state long enough to allow selection of properly targeted cell colonies with a high frequency of homologous recombination. Furthermore, blastocysts cloned from cultured murine ES cells develop to term at an efficiency (10–30%) that is three to ten times higher than blastocysts cloned from the nuclei of differentiated somatic cells. It seems likely that ES cells require less extensive reprogramming than do somatic cells, perhaps because in ES cells, many genes that are essential for early development are already active and thus do not require reactivation.Recently, we succeeded in isolating immortalized equine and bovine ES cells with a normal karyotype, that exhibit features similar to those of murine ES cells and express Oct 4, STAT-3, SSEA-1 and Ap. We further confirmed the pluripotential ability of these cells, which were able to undergo somatic differentiation in vitro to neural progenitors and to endothelial or hematopoietic lineages. We were able to use bovine ES cells, as a source of nuclei for nuclear transfer (NT) and we generated cloned cattle with a higher frequency of pregnancies to term than has been achieved with differentiated somatic cells. Moreover, bovine ES cells that expressed enhanced green fluorescent protein (EGFP) were incorporated into both the inner cell mass (ICM) and the trophectdermal cells of developing blastocysts. These findings should facilitate targeted genetic manipulation of the genome and should allow production of cloned cattle in a single step after modification, as appropriate, of the genome.

Derivation, Maintenance, and Induction of the Differentiation In Vitro of Equine Embryonic Stem Cells

We describe here the isolation and maintenance of pluripotent embryonic stem (ES) cells from equine blastocysts that have been frozen and thawed. Equine ES cells appear to maintain a normal diploid karyotype in culture. These cells express markers that are characteristic of mouse ES cells, namely, alkaline phosphatase, stage-specific-embryonic antigen 1, STAT3, and Oct4. We also describe protocols for the induction of differentiation in vitro to neural precursor cells in the presence of basic fibroblast growth factor (bFGF), epidermal growth factor, and platelet-derived growth factor and to hematopoietic and endothelial cell lineages in the presence of bFGF, stem cell factor, and oncostatin M. Equine ES cells provide a powerful tool for gene targeting and the generation of transgenic clonal offspring.

Androgen receptor-mediated apoptosis in bovine testicular induced pluripotent stem cells in response to phthalate esters.

The androgen receptor (AR) has a critical role in promoting androgen-dependent and -independent apoptosis in testicular cells. However, the molecular mechanisms that underlie the ligand-independent apoptosis, including the activity of AR in testicular stem cells, are not completely understood. In the present study, we generated induced pluripotent stem cells (iPSCs) from bovine testicular cells by electroporation of octamer-binding transcription factor 4 (OCT4). The cells were supplemented with leukemia inhibitory factor and bone morphogenetic protein 4, which maintained and stabilized the expression of stemness genes and pluripotency. The iPSCs were used to assess the apoptosis activity following exposure to phthalate esters, including di (2-ethyhexyl) phthalates, di (n-butyl) phthalate, and butyl benzyl phthalate. Phthalate esters significantly reduced the expression of AR in iPSCs and induced a higher ratio of BAX/BCL-2, thereby favoring apoptosis. Phthalate esters also increased the expression of cyclin-dependent kinase inhibitor 1 (p21Cip1) in a p53-dependent manner and enhanced the transcriptional activity of p53. The forced expression of AR and knockdown of p21Cip1 led to the rescue of the phthalate-mediated apoptosis. Overall, this study suggests that testicular iPSCs are a useful system for screening the toxicity of environmental disruptors and examining their effect on the maintenance of stemness and pluripotency, as well as for identifying the iPSC signaling pathway(s) that are deregulated by these chemicals.

Emerging roles of hypoxia-inducible factors and reactive oxygen species in cancer and pluripotent stem cells.

Eukaryotic organisms require oxygen homeostasis to maintain proper cellular function for survival. During conditions of low oxygen tension (hypoxia), cells activate the transcription of genes that induce an adaptive response, which supplies oxygen to tissues. Hypoxia and hypoxia‐inducible factors (HIFs) may contribute to the maintenance of putative cancer stem cells, which can continue self‐renewal indefinitely and express stemness genes in hypoxic stress environments (stem cell niches). Reactive oxygen species (ROS) have long been recognized as toxic by‐products of aerobic metabolism that are harmful to living cells, leading to DNA damage, senescence, or cell death. HIFs may promote a cancer stem cell state, whereas the loss of HIFs induces the production of cellular ROS and activation of proteins p53 and p16Ink4a, which lead to tumor cell death and senescence. ROS seem to inhibit HIF regulation in cancer cells. By contrast, controversial data have suggested that hypoxia increases the generation of ROS, which prevents hydroxylation of HIF proteins by inducing their transcription as negative feedback. Moreover, hypoxic conditions enhance the generation of induced pluripotent stem cells (iPSCs). During reprogramming of somatic cells into a PSC state, cells attain a metabolic state typically observed in embryonic stem cells (ESCs). ESCs and iPSCs share similar bioenergetic metabolisms, including decreased mitochondrial number and activity, and induced anaerobic glycolysis. This review discusses the current knowledge regarding the emerging roles of ROS homeostasis in cellular reprogramming and the implications of hypoxic regulation in cancer development.

Positive Feedback Loop of OCT4 and c‐JUN Expedites Cancer Stemness in Liver Cancer

The network of stemness genes and oncogenes in human patient‐specific reprogrammed cancer stem cells (CSCs) remains elusive, especially in liver cancer. HepG2‐derived induced pluripotent stem cell‐like cells (HepG2‐iPS‐like cells) were generated by introducing Yamanaka factors and the knockdown vector shTP53. They exhibited features of stemness and a higher tumorigenesis after xenograft transplantation compared with HepG2 cells. The cancerous mass of severe combined immunodeficiency (SCID) mice derived from one colony was dissected and cultured to establish reprogrammed HepG2‐derived CSC‐like cells (designated rG2‐DC‐1C). A single colony exhibited 42% occurrence of tumors with higher proliferation capacities. rG2‐DC‐1C showed continuous expression of the OCT4 stemness gene and of representative tumor markers, potentiated chemoresistance characteristics, and invasion activities. The sphere‐colony formation ability and the invasion activity of rG2‐DC‐1C were also higher than those of HepG2 cells. Moreover, the expression of the OCT4 gene and the c‐JUN oncogene, but not of c‐MYC, was significantly elevated in rG2‐DC‐1C, whereas no c‐JUN expression was observed in HepG2 cells. The positive‐feedback regulation via OCT4‐mediated transactivation of the c‐JUN promoter and the c‐JUN‐mediated transactivation of the OCT4 promoter were crucial for promoting cancer development and maintaining cancer stemness in rG2‐DC‐1C. Increased expression of OCT4 and c‐JUN was detected in the early stage of human liver cancer. Therefore, the positive feedback regulation of OCT4 and c‐JUN, resulting in the continuous expression of oncogenes such as c‐JUN, seems to play a critical role in the determination of the cell fate decision from iPS cells to CSCs in liver cancer. Stem Cells 2016;34:2613–2624

Oncogenic function of the homeobox A13-long noncoding RNA HOTTIP-insulin growth factor-binding protein 3 axis in human gastric cancer

To study the mechanisms of gastric tumorigenesis, we have established CSN cell line from human normal gastric mucosa, and CS12, a tumorigenic and invasive gastric cancer cell line from CSN passages. Many stem cell markers were expressed in both CSN and CS12 cells, but LGR5 and NANOG were expressed only in CS12 cells. Increased expression of homeobox A13 (HoxA13) and its downstream cascades was significant for the tumorigenic activity of CS12 cells, and was associated with recruitment of E2F-1 to HoxA13 promoter accompanied with increased trimethylation of histone H3 lysine 4 (H3K4me3) at the hypomethylated E2F motifs. Knockdown of HoxA13 caused the downregulation of long non-coding RNA HOTTIP and insulin growth factor-binding protein 3 (IGFBP-3) genes, indicating that both were targets of HoxA13. Concurrent regulation of HoxA13-HOTTIP was mediated by the mixed lineage leukemia-WD repeat domain 5 complex, which caused the trimethylation of H3K4 and then stimulated cell proliferation. HoxA13 transactivated the IGFBP-3 promoter through the HOX-binding site. Activation of IGFBP-3 stimulated the oncogenic potential and invasion activity. Increased expression of HoxA13 (63.2%) and IGFBP-3 (28.6%) was detected in human gastric cancer tissues and was found in the gastric cancer data of The Cancer Genome Atlas. Taken together, the HoxA13–HOTTIP–IGFBP-3 cascade is critical for the carcinogenic characteristics of CS12 cells.

Jun dimerization protein 2 controls senescence and differentiation via regulating histone modification.

Transcription factor, Jun dimerization protein 2 (JDP2), binds directly to histones and DNAs and then inhibits the p300-mediated acetylation both of core histones and of reconstituted nucleosomes that contain JDP2 recognition DNA sequences. JDP2 plays a key role as a repressor of adipocyte differentiation by regulation of the expression of the gene C/EBPδ via inhibition of histone acetylation. Moreover, JDP2-deficient mouse embryonic fibroblasts (JDP2−/− MEFs) are resistant to replicative senescence. JDP2 inhibits the recruitment of polycomb repressive complexes (PRC1 and PRC2) to the promoter of the gene encoding p16Ink4a, resulting from the inhibition of methylation of lysine 27 of histone H3 (H3K27). Therefore, it seems that chromatin-remodeling factors, including the PRC complex controlled by JDP2, may be important players in the senescence program. The novel mechanisms that underline the action of JDP2 in inducing cellular senescence and suppressing adipocyte differentiation are reviewed.