oct4‐EGFP reporter gene expression marks the stem cells in embryonic development and in adult gonads of transgenic medaka

Maintenance of pluripotency in stem cells is tightly regulated among vertebrates. One of the key genes in this process is oct4, also referred to as pou5f1 in mammals and pou2 in teleosts. Pou5f1 evolved by duplication of pou2 early in the tetrapod lineage, but only monotremes and marsupials retained both genes. Either pou2 or pou5f1 was lost from the genomes of the other tetrapods that have been analyzed to date. Consequently, these two homologous genes are often designated oct4 in functional studies. In most vertebrates oct4 is expressed in pluripotent cells of the early embryo until the blastula stage, and later persist in germline stem cells until adulthood. The isolation and analysis of stem cells from embryo or adult individuals is hampered by the need for reliable markers that can identify and define the cell populations. Here, we report the faithful expression of EGFP under the control of endogenous pou2/oct4 promoters in transgenic medaka (Oryzias latipes). In vivo imaging in oct4‐EGFP transgenic medaka reveals the temporal and spatial expression of pou2 in embryos and adults alike. We describe the temporal and spatial patterns of endogenous pou2 and oct4‐EGFP expression in medaka with respect to germline and adult stem cells, and discuss applications of oct4‐EGFP transgenic medaka in reproductive and stem cell biology. Mol. Reprod. Dev. 80: 48–58, 2013. © 2012 Wiley Periodicals, Inc.     

Molecular Reproduction & Development Volume 80, Issue 1, January 2013 cover image

Several types of stem cells are characterized by the expression of oct4 in vertebrates. In transgenic medaka (Oryzias latipes) generated by Froschauer et al. (this issue), oct4‐ EGFP expression marks the stem cells in development and in adult testis, in which the spermatogonia are found at the distal ends of the testicular tubules (background, red). When the fluorescence of these EGFP‐positive cells is quantified by flow cytometry (foreground), the spermatogonia elicit the strongest fluorescence (horizontal axis).     

Pluripotency of a polyploid H1 (ES) cell system without leukaemia inhibitory factor

Objectives: Tetraploid cells are strictly biologically inhibited from composition of embryos; by the same token, only diploid cells compose embryos. However, the distinction between diploid and tetraploid cells in development has not been well explained. To examine pluripotency of polyploid ES cells, a polyploid embryonic stem (ES)‐cell system was prepared. Materials and methods: Diploid, tetraploid, pentaploid, hexaploid, octaploid and decaploid H1 (ES) cells (2H1, 4H1, 5H1, 6H1, 8H1 and 10H1 cells, respectively) were cultured for about 460 days in L15F10 medium without leukaemia inhibitory factor (LIF). The cells cultured under LIF‐free conditions were denoted as 2H1(?), 4H1(?), 5H1(?), 6H1(?), 8H1(?) and 10H1(?) cells, respectively. Pluripotency and gene expression were examined. Results: Ploidy alteration of H1(?) cells was similar to that of H1 cells. The polyploid H1(?) cells showed positive activity of alkaline phosphatase, suggesting that they maintained pluripotency in vitro without LIF. The polyploid H1(?) cells formed teratocarcinomas in mouse abdomen, suggesting they could differentiate in mouse abdomen in vivo. 2H1, 4H1 and polyploid H1(?) cells expressed nanog, oct3/4 and sox2 genes, suggesting that they fulfilled the criteria of ES cells. Nanog gene was significantly over‐expressed in 4H1 and polyploid H1(?) cells, suggesting that overexpression of nanog gene was a characteristic of polyploid H1 cells. Conclusion: Polyploid H1 (ES) cells retained pluripotency in vitro, without LIF with nanog over‐expression.     

斑马鱼多能性因子的研究进展

哺乳动物多能性因子, 主要包括Pou5f1/Oct4、Sox2、Klf4、Nanog等转录因子, 不仅能够维持胚胎干细胞的未分化状态, 同时也参与使分化细胞重编程回多能性状态的过程。目前对脊椎动物多能性因子在体(in vivo)功能研究报道极少。斑马鱼是研究脊椎动物早期发育分化的理想模型, 它能够为多能性相关因子的功能研究提供在体环境, 因而可以更准确地了解多能性因子的作用信息。近年来, 已在斑马鱼中发现了多种哺乳动物多能性因子的同源基因, 如oct4、nanog等。文章主要介绍了斑马鱼中多能性因子的相关研究进展, 并与其它动物中的研究作一比较。     

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。     

Fish stem cell cultures

Stem cells have the potential for self-renewal and differentiation. First stem cell cultures were derived 30 years ago from early developing mouse embryos. These are pluripotent embryonic stem (ES) cells. Efforts towards ES cell derivation have been attempted in other mammalian and non-mammalian species. Work with stem cell culture in fish started 20 years ago. Laboratory fish species, in particular zebrafish and medaka, have been the focus of research towards stem cell cultures. Medaka is the second organism that generated ES cells and the first that gave rise to a spermatogonial stem cell line capable of test-tube sperm production. Most recently, the first haploid stem cells capable of producing whole animals have also been generated from medaka. ES-like cells have been reported also in zebrafish and several marine species. Attempts for germline transmission of ES cell cultures and gene targeting have been reported in zebrafish. Recent years have witnessed the progress in markers and procedures for ES cell characterization. These include the identification of fish homologs/paralogs of mammalian pluripotency genes and parameters for optimal chimera formation. In addition, fish germ cell cultures and transplantation have attracted considerable interest for germline transmission and surrogate production. Haploid ES cell nuclear transfer has proven in medaka the feasibility of semi-cloning as a novel assisted reproductive technology. In this special issue on "Fish Stem Cells and Nuclear Transfer", we will focus our review on medaka to illustrate the current status and perspective of fish stem cells in research and application. We will also mention semi-cloning as a new development to conventional nuclear transfer.     

Establishment and growth responses of Nile tilapia embryonic stem‐like cell lines under feeder‐free condition

Embryonic stem (ES) cells provide an invaluable tool for molecular analysis of vertebrate development and a bridge linking genomic manipulations in vitro and functional analysis of target genes in vivo. Work towards fish ES cells so far has focused on zebrafish (Danio renio) and medaka (Oryzias latipes). Here we describe the derivation, pluripotency, differentiation and growth responses of ES cell lines from Nile tilapia (Oreochromis niloticus), a world‐wide commercial farmed fish. These cell lines, designated as TES1‐3, were initiated from blastomeres of Nile tilapia middle blastula embryos (MBE). One representative line, TES1, showed stable growth and phenotypic characteristics of ES cells over 200 days of culture with more than 59 passages under feeder‐free conditions. They exhibited high alkaline phosphatase activity and expression of pluripotency genes including pou5f3 (the pou5f1/oct4 homologue), sox2, myc and klf4. In suspension culture together with retinoic acid treatment, TES1 cells formed embryoid bodies, which exhibited expression profile of differentiation genes characteristics of all three germ cell layers. Notably, PKH26‐labeled TES1 cells introduced into Nile tilapia MBE could contribute to body compartment development and led to hatched chimera formation with an efficacy of 13%. These results suggest that TES1 cells have pluripotency and differentiation potential in vitro and in vivo. In the conditioned DMEM, all of the supplements including the fetal bovine serum, fish embryonic extract, fish serum, basic fibroblast growth factor and non‐protein supplement combination 5N were mitogenic for TES1 cell growth. This study will promote ES‐based biotechnology in commercial fish.     

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.     

Chromatin signatures of pluripotent cell lines

Epigenetic genome modifications are thought to be important for specifying the lineage and developmental stage of cells within a multicellular organism. Here, we show that the epigenetic profile of pluripotent embryonic stem cells (ES) is distinct from that of embryonic carcinoma cells, haematopoietic stem cells (HSC) and their differentiated progeny. Silent, lineage-specific genes replicated earlier in pluripotent cells than in tissue-specific stem cells or differentiated cells and had unexpectedly high levels of acetylated H3K9 and methylated H3K4. Unusually, in ES cells these markers of open chromatin were also combined with H3K27 trimethylation at some non-expressed genes. Thus, pluripotency of ES cells is characterized by a specific epigenetic profile where lineage-specific genes may be accessible but, if so, carry repressive H3K27 trimethylation modifications. H3K27 methylation is functionally important for preventing expression of these genes in ES cells as premature expression occurs in embryonic ectoderm development (Eed)-deficient ES cells. Our data suggest that lineage-specific genes are primed for expression in ES cells but are held in check by opposing chromatin modifications.