Zhaohui Kou

Dynamic Reprogramming of Histone Acetylation and Methylation in the First Cell Cycle of Cloned Mouse Embryos

Abstract Epigenetic reprogramming is thought to play an important role in the development of cloned embryos reconstructed by somatic cell nuclear transfer (SCNT). In the present study, dynamic reprogramming of histone acetylation and methylation modifications was investigated in the first cell cycle of cloned embryos. Our results demonstrated that part of somatic inherited lysine acetylation on core histones (H3K9, H3K14, H4K16) could be quickly deacetylated following SCNT, and reacetylation occurred following activation treatment. However, acetylation marks of the other lysine residues on core histones (H4K8, H4K12) persisted in the genome of cloned embryos with only mild deacetylation occurring in the process of SCNT and activation treatment. The somatic cloned embryos established histone acetylation modifications resembling those in normal embryos produced by intracytoplasmic sperm injection through these two different programs. Moreover, treatment of cloned embryos with a histone deacetylase inhibitor, Trichostatin A (TSA), improved the histone acetylation in a manner similar to that in normal embryos, and the improved histone acetylation in cloned embryos treated with TSA might contribute to improved development of TSA-treated clones. In contrast to the asymmetric histone H3K9 tri- and dimethylation present in the parental genomes of fertilized embryos, the tri- and dimethylations of H3K9 were gradually demethylated in the cloned embryos, and this histone H3K9 demethylation may be crucial for gene activation of cloned embryos. Together, our results indicate that dynamic reprogramming of histone acetylation and methylation modifications in cloned embryos is developmentally regulated.

Proteome of mouse oocytes at different developmental stages

The mammalian oocyte possesses powerful reprogramming factors, which can reprogram terminally differentiated germ cells (sperm) or somatic cells within a few cell cycles. Although it has been suggested that use of oocyte-derived transcripts may enhance the generation of induced pluripotent stem cells, the reprogramming factors in oocytes are undetermined, and even the identified proteins composition of oocytes is very limited. In the present study, 7,000 mouse oocytes at different developmental stages, including the germinal vesicle stage, the metaphase II (MII) stage, and the fertilized oocytes (zygotes), were collected. We successfully identified 2,781 proteins present in germinal vesicle oocytes, 2,973 proteins in MII oocytes, and 2,082 proteins in zygotes through semiquantitative MS analysis. Furthermore, the results of the bioinformatics analysis indicated that different protein compositions are correlated with oocyte characteristics at different developmental stages. For example, specific transcription factors and chromatin remodeling factors are more abundant in MII oocytes, which may be crucial for the epigenetic reprogramming of sperm or somatic nuclei. These results provided important knowledge to better understand the molecular mechanisms in early development and may improve the generation of induced pluripotent stem cells.

Interspecies Implantation and Mitochondria Fate of Panda-Rabbit Cloned Embryos

Abstract Somatic cell nuclei of giant pandas can dedifferentiate in enucleated rabbit ooplasm, and the reconstructed eggs can develop to blastocysts. In order to observe whether these interspecies cloned embryos can implant in the uterus of an animal other than the panda, we transferred approximately 2300 panda-rabbit cloned embryos into 100 synchronized rabbit recipients, and none became pregnant. In another approach, we cotransferred both panda-rabbit and cat-rabbit interspecies cloned embryos into the oviducts of 21 cat recipients. Fourteen recipients exhibited estrus within 35 days; five recipients exhibited estrus 43–48 days after embryo transfer; and the other two recipients died of pneumonia, one of which was found to be pregnant with six early fetuses when an autopsy was performed. Microsatellite DNA analysis of these early fetuses confirmed that two were from giant panda-rabbit cloned embryos. The results demonstrated that panda-rabbit cloned embryos can implant in the uterus of a third species, the domestic cat. By using mitochondrial-specific probes of panda and rabbit, we found that mitochondria from both panda somatic cells and rabbit ooplasm coexisted in early blastocysts, but mitochondria from rabbit ooplasm decreased, and those from panda donor cells dominated in early fetuses after implantation. Our results reveal that mitochondria from donor cells may substitute those from recipient oocytes in postimplanted, interspecies cloned embryos.

The Histone Demethylase JMJD2C Is Stage-Specifically Expressed in Preimplantation Mouse Embryos and Is Required for Embryonic Development

Abstract Epigenetic modifications play a pivotal role in embryonic development by dynamically regulating DNA methylation and chromatin modifications. Although recent studies have shown that core histone methylation is reversible, very few studies have investigated the functions of the newly discovered histone demethylases during embryonic development. In the present study, we investigated the expression characteristics and function of JMJD2C, a histone demethylase that belongs to the JmjC-domain-containing histone demethylases, during preimplantation embryonic development of the mouse. We found that JMJD2C is stage-specifically expressed during preimplantation development, with the highest activity being observed from the two-cell to the eight-cell stage. Depletion of JMJD2C in metaphase II oocytes followed by parthenogenetic activation causes a developmental arrest before the blastocyst stage. Moreover, consistent with a previous finding in embryonic stem (ES) cells, depletion of JMJD2C causes a significant down-regulation of the pluripotency gene Nanog in embryos. However, contrary to a previous report in ES cells, we observed that other pluripotency genes, Pou5f1 and Sox2, are also significantly down-regulated in JMJD2C-depleted embryos. Furthermore, the depletion of JMJD2C in early embryos also caused significant down-regulation of the Myc and Klf4 genes, which are associated with cell proliferation. Our data suggest that the deregulation of these critical genes synergistically causes the developmental defects observed in JMJD2C-depleted embryos.

Reprogramming of Trophoblast Stem Cells into Pluripotent Stem Cells by Oct4

ESCs and trophoblast stem (TS) cells are both derived from early embryos, yet these cells have distinct differentiation properties. ESCs can differentiate into all three germ layer cell types, whereas TS cells can only differentiate into placental cells. It has not been determined whether TS cells can be converted into ES‐like pluripotent stem (PS) cells. Here, we report that overexpression of a single transcription factor, Oct4, in TS cells is sufficient to reprogram TS cells into a pluripotent state. These Oct4‐induced PS (OiPS) cells have the epigenetic characteristics of ESCs, including X chromosome reactivation, elevated H3K27 me3 modifications, and hypomethylation of promoter regions in Oct4 and Nanog genes. Meanwhile, methylation of promoter region in the Elf5 gene occurred during reprogramming of TS cells. The gene expression profile of OiPS cells was very similar to ESCs. Moreover, OiPS cells can differentiate into the three germ layer cell types in vitro and in vivo. More importantly, chimeric mice with germline transmission could be efficiently produced from OiPS cells. Our results demonstrate that one single transcription factor, Oct4, could reprogram the nonembryonic TS cells into PS cells. STEM CELLS 2011;29:755–763

Defective Chromatin Structure in Somatic Cell Cloned Mouse Embryos

Epigenetic reprogramming plays a central role in the development of cloned embryos generated by somatic cell nuclear transfer, and it is believed that aberrant reprogramming leads to the abnormal development of most cloned embryos. Recent studies show that trimethylation of H3K27 (H3K27me3) contributes to the maintenance of embryonic stem cell pluripotency because the differentiation genes are always occupied by nucleosomes trimethylated at H3K27, which represses gene expression. Here, we provide evidence that differential H3K27me3 modification exists between normal fertilization-produced blastocysts and somatic cell nuclear transfer cloned blastocysts; H3K27me3 was specifically found in cells of the inner cell mass (ICM) of normal blastocysts, whereas there was no modification of H3K27me3 in the ICM of cloned blastocysts. Subsequently, we demonstrated that the differentiation-related genes, which are marked by H3K27me3 in embryonic stem cells, were expressed at significantly higher levels in cloned embryos than in normal embryos. The polycomb repressive complex 2 (PRC2) component genes (Eed, Ezh2, and Suz12), which are responsible for the generation of H3K27me3, were expressed at lower levels in the cloned embryos. Our results suggest that reduced expression of PRC2 component genes in cloned embryos results in defective modification of H3K27me3 to the differentiation-related genes in pluripotent ICM cells. This results in premature expression of developmental genes and death of somatic cloned embryos shortly after implantation. Taken together, these studies suggest that H3K27me3 might be an important epigenetic marker with which to evaluate the developmental potential of cloned embryos.

Novel Importin-α Family Member Kpna7 Is Required for Normal Fertility and Fecundity in the Mouse

Nuclear importing system and nuclear factors play important roles in mediating nuclear reprogramming and zygotic gene activation. However, the components and mechanisms that mediate nuclearly specific targeting of the nuclear proteins during nuclear reprogramming and zygotic gene activation remain largely unknown. Here, we identified a novel member of the importin-α family, AW146299(KPNA7), which is predominantly expressed in mouse oocytes and zygotes and localizes to the nucleus or spindle. Mutation of Kpna7 gene caused reproductivity reduction and sex imbalance by inducing preferential fetal lethality in females. Parthenogenesis analysis showed that the cell cycle of activated one-cell embryos is loss of control and ahead of schedule but finally failed to develop into blastocyst stage. Further RT-PCR and epigenetic modification analysis showed that knocking out of Kpna7 induced abnormalities of gene expression (dppa2, dppa4, and piwil2) and epigenetic modifications (down-regulation of histone H3K27me3). Biochemical analysis showed that KPNA7 interacts with KPNB1 (importin-β1). In summary, we identified a novel Kpna7 gene that is required for normal fertility and fecundity.

Mouse Meningiocytes Express Sox2 and Yield High Efficiency of Chimeras after Nuclear Reprogramming with Exogenous Factors

Induced pluripotent stem cell technology, also termed iPS, is an emerging approach to reprogram cells into an embryonic stem cell-like state by viral transduction with defined combinations of factors. iPS cells share most characteristics of embryonic stem cells, counting pluripotency and self-renewal, and have so far been obtained from mouse and humans, including patients with genetic diseases. Remarkably, autologous transplantation of cell lineages derived from iPS cells will eliminate the possibility of immunological rejection, as well as current ethical issues surrounding human embryonic stem cell research. However, before iPS can be used for clinical purposes, technical problems must be overcome. Among other considerations, full and homogeneous iPS reprogramming is an important prerequisite. However, despite the fact that cells from several mouse tissues can be successfully induced to iPS, the overall efficiency of chimera formation of these clones remains low even if selection for Oct4 or Nanog expression is applied. In this report, we demonstrate that cells from the mouse meningeal membranes express elevated levels of the embryonic master regulator Sox2 and are highly amenable to iPS. Meningeal iPS clones, generated without selection, are fully and homogeneously reprogrammed based on DNA methylation analysis and 100% chimera competent. Our results define a population of somatic cells that are ready to undergo iPS, thus highlighting a very attractive cell type for iPS research and application.

Promoting Reprogramming by FGF2 Reveals that the Extracellular Matrix Is a Barrier for Reprogramming Fibroblasts to Pluripotency

Leukemia inhibitory factor and bone morphogenetic protein signaling pathways play important roles in maintaining the self‐renewal of mouse embryonic stem cells (ESCs). In contrast, the supplementation of fibroblast growth factor 2 (FGF2) in culture promotes mouse ESC differentiation. It has been proposed that factors that are adverse for maintaining the self‐renewal of ESCs might play detrimental roles in the transcription factor‐mediated reprogramming of somatic cells to pluripotency. However, recent evidence has revealed that reprogramming efficiency could be improved by FGF2, while the underlying molecular mechanism remains unknown. In this study, we dissected the roles of FGF2 in promoting mouse fibroblast reprogramming and disclosed the molecular mechanism behind this process. We used both primary induction and secondary inducible reprogramming systems and demonstrated that supplementation with FGF2 in the early phase of induced pluripotent stem cell induction could significantly increase reprogramming efficiency. Moreover, we discovered that many extracellular matrix candidate genes were significantly downregulated in fibroblasts treated with FGF2, and in particular, the synthesis of collagen could be greatly reduced by FGF2 treatment. Subsequently, we demonstrated that collagen is a barrier for reprogramming fibroblast cells to pluripotency, and the decreasing of collagen either by collagenase treatment or downregulation of collagen gene expression could significantly improve the reprogramming efficiency. Our results reveal a novel role of the extracellular matrix in mediating fibroblasts reprogramming. STEM CELLS 2013;31:729–740

Mice Cloned from Induced Pluripotent Stem Cells (iPSCs)

Differentiated somatic cells of various species can be reprogrammed into induced pluripotent stem cells (iPSCs) by ectopically expressing a combination of several transcription factors that are highly enriched in embryonic stem cells (ESCs). The generation of iPSCs in large animals has raised the possibility of producing genetically modified large animals through the nuclear transplantation approach. However, it remains unknown whether iPSCs could be used for generating cloned animals through the nuclear transfer method. Here, we show the successful production of viable cloned mice from inducible iPSCs through the nuclear transfer approach, and the efficiency is similar to that of using ESCs derived via normal fertilization. Furthermore, the cloned mice are fertile and can produce second-generation offspring. These efforts strengthen the possibility of utilizing iPSCs to generate gene-modified large animals for pharmaceutical purposes in the future.