Exogenous expression of homeoprotein EGAM1N prevents in vitro cardiomyogenesis by impairing expression of T and Nkx2.5, but not Mef2c, in mouse embryonic stem cells.

Generation of multiple cell types from embryonic stem (ES) cells and induced pluripotent stem cells is crucial to provide materials for regenerative medicine. EGAM1N has been found in preimplantation mouse embryos and mouse ES cells as a functionally unclassified homeoprotein. Recently, we reported that expression of EGAM1N suppressed the in vitro differentiation of ES cells into progenitor cells that arise in early embryogenesis. To clarify the effect of EGAM1N on terminal differentiation, embryoid bodies (EBs) were prepared from ES cells expressing exogenous Egam1n. In EBs expressing Egam1n, cardiomyogenesis was inhibited by impairing the expression of crucial transcription factors Brachyury T and Nkx2.5 in the generation of mesoderm and cardiomyocytes, respectively. Expression levels of Mef2c, another crucial gene for cardiomyogenesis, were unaffected. Conversely, the expression levels of Gata6 and Plat, markers for the primitive endoderm lineage, and Cdx2, a marker for the trophectoderm lineage, were increased. These results suggested that certain cell populations in EBs expressing Egam1n preferentially differentiated to such cell lineages. Our results suggest that EGAM1N not only affects the generation of progenitor cells during early embryogenesis, but also the progression of terminal differentiation, such as cardiomyogenesis, in mouse ES cells.

A Simple and Efficient Method of Slow Freezing for Human Embryonic Stem Cells and Induced Pluripotent Stem Cells.

Protocols available for the cryopreservation of human embryonic stem (ES) and induced pluripotent stem (iPS) cells are very inefficient and laborious compared to those for the cryopreservation of murine ES/iPS cells or other general cell lines. While the vitrification method may be adequate when working with small numbers of human ES/iPS cells, it requires special skills and is unsuitable when working with large cell numbers. Here, we describe a simple and efficient method for the cryopreservation of hES/hiPS cells that is based on a conventional slow freezing method that uses a combination of Pronase/EDTA for Stem™ and CP-5E™ [final concentrations: 6 % hydroxyethyl starch, 5 % DMSO, and 5 % ethylene glycol in saline]. CP-5E™ is highly effective for the cryopreservation of small cell clumps produced by hES/hiPS colony detachment in the presence of Pronase and EDTA (Pronase/EDTA for Stem™, a formulation containing multiple digestive enzymes from Streptomyces griseus). This novel method would be quite useful for large-scale hES/iPS cell banking for use in clinical applications.

Intact structure of EGAM1 homeoproteins and basic amino acid residues in the common homeodomain of EGAM1 and EGAM1C contribute to their nuclear localization in mouse embryonic stem cells.

Recently, we identified the structurally related homeoproteins EGAM1, EGAM1N, and EGAM1C in both preimplantation mouse embryos and mouse embryonic stem (ES) cells. These EGAM1 homeoproteins act as positive or negative regulators of differentiation and cell growth in mouse ES cells, such that these proteins are considered transcriptional regulators. In this study, we investigated their nuclear localization and identified the amino acid residues crucial for the nuclear translocation of EGAM1 and EGAM1C. When expressed exogenously in pluripotent ES cells and somatic NIH3T3 cells, all EGAM1 homeoproteins localized to the nucleus. Analysis using the web-based tool PSORTII predicted a potential nuclear localization signal (NLS) motif, RKDLIRSWFITQRHR, in the homeodomain shared by EGAM1 and EGAM1C. The introduction of mutations, such as mutations from K or R, both basic amino acid residues, to A, in this potential NLS resulted in significant impairment of the nuclear localization of both EGAM1 and EGAM1C. In contrast, GFP fusion proteins of all the full-length EGAM1 homeoproteins failed to localize to the nucleus. These results, when taken together, suggest that basic amino acid residues in the common homeodomain of EGAM1 and EGAM1C and the intact structures of the EGAM1 homeoproteins contribute, at least in part, to the nuclear localization of these proteins in mouse ES cells.

Severe inhibition of in vitro cardiomyogenesis in mouse embryonic stem cells ectopically expressing EGAM1C homeoprotein.

Embryoid bodies were prepared from mouse embryonic stem cells expressing exogenous EGAM1C to analyze their ability to differentiate toward terminally differentiated cell types. The generation of cardiomyocytes was severely suppressed in Egam1c transfectants without upregulation of Nkx2-5, a crucial gene for cardiomyogenesis. These results indicate that EGAM1C is capable of affecting terminal differentiation in mouse embryonic stem cells.

Preferential emergence of cell types expressing markers for primitive endoderm lineages in mouse embryonic stem cells expressing exogenous EGAM1 homeoprotein.

Embryonic stem (ES) cells have been considered as a valuable renewable source of materials in regenerative medicine. Recently, we identified the homeoprotein EGAM1 both in preimplantation mouse embryos and mouse ES cells. Expression of the Egam1 transcript and its encoded protein was detectable in differentiating mouse ES cells, while it was almost undetectable in undifferentiated cells. In the present study, in order to clarify the effect of forced expression of EGAM1 on the differentiation of mouse ES cells in vitro, transfectants expressing exogenous EGAM1 were generated. Egam1 transfectants promoted differentiation into cell types expressing Gata6, Gata4, Afp, or Plat, genes associated with emergence of the extra-embryonic endoderm lineages. On the other hand, Egam1 transfectants inhibited the expression of specific genes for the embryonic lineages, including Fgf5 (epiblast) and T (mesoderm), in addition to Cdx2, a specific gene for the extra-embryonic trophectoderm lineages. Changes in the percentage of cells recognizing by antibodies against specific marker proteins closely correlated with the expression patterns of their transcripts. Taken together, the results obtained in this study suggested that mouse ES cells expressing exogenous EGAM1 preferentially differentiate into extra-embryonic primitive endoderm lineages, rather than embryonic lineages or extra-embryonic trophectoderm lineages.

Common nucleotide sequence of structural gene encoding fibroblast growth factor 4 in eight cattle derived from three breeds.

Fibroblast growth factor 4 (FGF4) is considered as a crucial gene for the proper development of bovine embryos. However, the complete nucleotide sequences of the structural genes encoding FGF4 in identified breeds are still unknown. In the present study, direct sequencing of PCR products derived from genomic DNA samples obtained from three Japanese Black, two Japanese Shorthorn and three Holstein cattle, revealed that the nucleotide sequences of the structural gene encoding FGF4 matched completely among these eight cattle. On the other hand, differences in the nucleotide sequences, leading to substitutions, insertions or deletions of amino acid residues were detected when compared with the already reported sequence from unidentified breeds. We cannot rule out a possibility that the structural gene elucidated in the present study is widely distributed in cattle. To the best of our knowledge, this is the first determination of the complete nucleotide sequence of the structural gene encoding bovine FGF4 in identified breeds.

Effect of ectopic expression of homeoprotein EGAM1C on the cell morphology, growth, and differentiation in a mouse embryonic stem cell line, MG1.19 cells.

The homeoprotein EGAM1C was identified in preimplantation mouse embryos and embryonic stem (ES) cells. To explore the impact of EGAM1C on the hallmarks of mouse ES cells, MG1.19 cells stably expressing EGAM1C at levels similar to those in blastocysts were established using an episomal expression system. In the presence of leukemia inhibitory factor (+LIF), control transfectants with an empty vector formed flattened cell colonies, while Egam1c transfectants formed compacted colonies with increased E-CADHERIN expression. In Egam1c transfectants, the cellular contents of POU5F1 (OCT4), SOX2, TBX3, and NANOG increased. Cell growth was accelerated in an undifferentiated state sustained by LIF and in the course of differentiation. During clonal proliferation, EGAM1C stabilized the undifferentiated state. In adherent culture conditions, EGAM1C partly inhibited the progression of differentiation at least within a 4-day culture period in the presence of retinoic acid by preventing the downregulation of LIF signaling with a robust increase in TBX3 expression. Conversely, EGAM1C enhanced the expression of lineage marker genes Fgf5 (epiblast), T (mesoderm), Gata6 (primitive endoderm), and Cdx2 (trophectoderm) in -LIF conditions. In embryoid bodies expressing EGAM1C, the expression of marker genes for extraembryonic cell lineages, including Tpbpa (spongiotrophoblast) and Plat (parietal endoderm), increased. These results demonstrated that the ectopic expression of EGAM1C is capable of affecting the stabilization of an undifferentiated state and the progression of differentiation in MG1.19 ES cells, in addition to affecting cellular morphology and growth.

Relationships between homeoprotein EGAM1C and the expression of the placental prolactin gene family in mouse placentae and trophoblast stem cells.

The mouse Crxos gene encodes three structurally related homeoproteins, EGAM1, EGAM1N, and EGAM1C, as transcription and splicing variants. Recently, we identified the functions of EGAM1 and EGAM1N in the regulation of differentiation in mouse embryonic stem cells. However, the function of EGAM1C remains unknown. To explore the additional roles of these proteins, the ontogenic expression of the respective mRNAs in post implantation mouse embryos and extraembryonic tissues, particularly from embryonic day (E) 10.5 to E18.5, was analyzed. The expression of Egam1n mRNA was specifically detected in embryos throughout this period, whereas that of Egam1 was undetectable in any of the tissues examined. However, in the placenta, Egam1c mRNA and its encoded protein were detected after E16.5, and these expression levels increased by E18.5 immediately before partum. Quantitative RT-PCR and in situ hybridization analyses in placentae revealed that the spatial and temporal expression patterns of the Egam1c mRNA were related to some extent with those of Prl3a1 and Prl5a1 and partially overlapped that of Prl3b1, which are members of the placental prolactin (PRL) gene family. When EGAM1C was overexpressed moderately in mouse trophoblast stem cells as a model for undifferentiated and differentiating placental cell types, the expression levels of endogenous Prl3b1 and Prl5a1 were enhanced under both undifferentiated and differentiating culture conditions. These results indicated that EGAM1C may play a role in the expression of members of the placental PRL gene family, such as Prl3b1 and Prl5a1.