Cloning Stem Cells最新文献

Among many factors that potentially affect somatic cell nuclear transfer (SCNT) embryo development is the donor cell itself. Cloning potentials of somatic donor cells vary greatly, possibly because the cells have different capacities to be reprogrammed by ooplasma. It is therefore intriguing to identify factors that regulate the reprogrammability of somatic donor cells. Gene expression analysis is a widely used tool to investigate underlying mechanisms of various phenotypes. In this study, we conducted a retrospective analysis investigating whether donor cell lines with distinct cloning efficiencies express different levels of genes involved in epigenetic reprogramming including histone deacetylase-1 (HDAC1), -2 (HDAC2); DNA methyltransferase-1 (DNMT1), -3a (DNMT3a),-3b (DNMT3b), and the bovine homolog of yeast sucrose nonfermenting-2 (SNF2L), a SWI/SNF family of ATPases. Cell samples from 12 bovine donor cell lines were collected at the time of nuclear transfer experiments and expression levels of the genes were measured using quantitative polymerase chain reaction (PCR). Our results show that there are no significant differences in expression levels of these genes between donor cell lines of high and low cloning efficiency defined as live calving rates, although inverse correlations are observed between in vitro embryo developmental rates and expression levels of HDAC2 and SNF2L. We also show that selection of stable reference genes is important for relative quantification, and different batches of cells can have different gene expression patterns. In summary, we demonstrate that expression levels of these epigenome regulatory genes in bovine donor cells are not correlated with cloning potential. The experimental design and data analysis method reported here can be applied to study any genes expressed in donor cells.

Recent findings identifying the transcription factors involved in the regulation of pluripotency and self-renewal in embryonic stem cells (ESC) may provide keys that enable the derivation of ESC in domestic species. In this study we monitored the expression of pluripotency-related genes in bovine inner cell mass (ICM) explants during the critical first steps in establishment of primary cultures. The expression of NANOG and POU5F1 transcripts and proteins in intact, in vitro produced (IVP) blastocysts was confirmed by quantitative RT-PCR and fluorescent immunocytochemistry. NANOG was localized to the nucleoplasm as well as the nucleoli in the ICM, whereas it appeared to be restricted to the nucleoli in trophectoderm cells. POU5F1 was localized in the nuclei of ICM and trophectoderm cells. ICM explants were analyzed by quantitative PCR and semiquantitative RT-PCR. The three major pluripotency-related transcription factors, NANOG, POU5F1, and SOX2, were expressed initially in the ICM explants, but were downregulated with subsequent culture. Markers of differentiation (BMP4, HNF4, NCAM, CDX2) and genes involved in LIF, BMP, and WNT signaling pathways were also expressed. ICM explants were cultured in the presence of various concentrations of cytokines belonging to the TGF-beta superfamily. Noggin, a cytokine inhibiting the BMP4 pathway, successfully upregulated the relative expression of NANOG mRNA in the ICM explants with respect to controls.

Mice are the most commonly used laboratory animals for research, and some mouse stem cells, such as induced pluripotent stem cells, embryonic stem cells, and mesenchymal stem cells (MSCs), are also widely used in basic research. It is thus important to know if these stem cells maintain their genomic stability when cultured. Murine bone marrow-derived mesenchymal stem cells (BMSCs) appear to undergo spontaneous transformation in vitro. Murine adipose tissue-derived mesenchymal stem cells (ADSCs), like BMSCs, have the potential to differentiate into multiple lineages. In this study, we used G-banding, induction of multiple-lineage differentiation, flow cytometry, and nuclear transfer (NT), and found that murine ADSCs also displayed chromosomal instability in long-term culture. Furthermore, we performed NT using murine ADSCs to study the nuclear reprogramming ability of undifferentiated adult stem cells and to find a new efficient donor for NT. Using the stem cells did not increase the percentage of NT embryos that developed to the morula/blastocyst stage, compared with cloned embryos from cumulus cells. This may be because the stem cells displayed chromosomal instability. This is the first reported study of the use of ADSCs for NT in mice. ADSCs could provide an alternative donor cell type for NT in other species, with the advantages of easy harvesting involving little or no pain or trauma.

Cloning in bovine species is marred by low efficiency of blastocyst formation. Any increase in the efficiency of blastocyst formation upon nuclear transfer will greatly enhance the efficiency of cloning. In the present study, the effect of various media, protein sources, and growth factors on the development of cloned buffalo embryos was evaluated. Among various combinations tested, culture of cloned embryos in TCM-199 media on the feeder layer of Buffalo Oviductal Epithelial Cells (BOEC) in the presence of bovine serum albumin-free fatty acid (BSA-FFA) and leukemia inhibitory factor (LIF) provided most suitable environment for efficient development of cloned blastocysts. Under these conditions, we achieved a blastocyst formation rate of 43%, which is better than those reported previously. Because preimplantation embryonic development, in vivo, occurs in an environment of oviductal cells, the blastocysts generated by this method may presumably be more suitable for implantation and further development. Additionally, we generated green blastocysts from enucleated oocytes by transfer of nuclei from cells transfected with EGFP transgene, showing possibility of transgenesis via cloning in this species. To our knowledge, this is the first report regarding the production of transgenic cloned buffalo embryos and their developmental competence with respect to various media, cocultures, and supplements.

Animal cloning has been associated with developmental abnormalities, with the level of heteroplasmy caused by the procedure being one of its potential limiting factors. The aim of this study was to determine the effect of the fusion of hemicytoplasts or aggregation of hemiembryos, varying the final cytoplasmic volume, on development and cell density of embryos produced by hand-made cloning (HMC), parthenogenesis or by in vitro fertilization (IVF). One or two enucleated hemicytoplasts were paired and fused with one skin somatic cell. Activated clone and zona-free parthenote embryos and hemiembryos were in vitro cultured in the well-of-the-well (WOW) system, being allocated to one of six experimental groups, on a per WOW basis: single clone or parthenote hemiembryos (1 x 50%); aggregation of two (2 x 50%), three (3 x 50%), or four (4 x 50%) clone or parthenote hemiembryos; single clone or parthenote embryos (1 x 100%); or aggregation of two clone or parthenote embryos (2 x 100%). Control zona-intact parthenote or IVF embryos were in vitro cultured in four-well dishes. Results indicated that the increase in the number of aggregated structures within each WOW was followed by a linear increase in cleavage, blastocyst rate, and cell density. The increase in cytoplasmic volume, either by fusion or by aggregation, had a positive effect on embryo development, supporting the establishment of pregnancies and the birth of a viable clone calf after transfer to recipients. However, embryo aggregation did not improve development on a hemicytoplast basis, except for the aggregation of two clone embryos.

Although successful nuclear transfer (NT) has been reported in the rat 6 years ago, somatic cell nuclear transfer (SCNT) in the rat could not be repeated. Our experiments with rat SCNT reveal the difficulties related to rat cloning. We first focussed on the most appropriate rat strain that could be used as an oocyte donor. Then we describe how rat oocytes can be kept in a nonactivated state during in vitro culture, because the latter undergo spontaneous partial activation through rapid extrusion of the second polar body after isolation from the oviduct. In the SCNT experiments performed with the one-step manipulation technique it was possible to produce rat embryos, which developed in vivo up to the blastocyst stage. In addition, we identified the implantation sites of SCNT rat embryos reconstructed with Sprague-Dawley (SD) oocytes. Furthermore, different rat strains were used as oocyte donors and their oocytes were cultured under different conditions to establish a stable nonactivating oocyte culture system. The ratio of activated to nonactivated oocytes was measured by spindle-stability and maturation promoting factor (MPF) activity. These measurements indicated that a substrain of the SD rat strain, the so-called OFA-SD strain, is the one providing the most stable oocytes, when their oocytes are cultured in the presence of the proteasome inhibitor MG132. However, it was not possible to obtain any implantation sites with reconstructed oocytes derived from the OFA-SD strain transferred to foster mothers. This goal was not achieved, even when the trichostatin A (TSA) treatment was used, which is known to enhance the cloning efficiency of reconstructed mouse, porcine, bovine, and rabbit oocytes both in vitro and in vivo by enhancing the reprogramming efficiency of the recipient nucleus.

Reprogramming of differentiated somatic cells into induced pluripotent stem (iPS) cells has potential for derivation of patient-specific cells for therapy as well as for development of models with which to study disease progression. Derivation of iPS cells from human somatic cells has been achieved by viral transduction of human fibroblasts with early developmental genes. Because forced expression of these genes by viral transduction results in transgene integration with unknown and unpredictable potential mutagenic effects, identification of cell culture conditions that can induce endogenous expression of these genes is desirable. Here we show that primary adult human fibroblasts have basal expression of mRNA for OCT4, SOX2, and NANOG. However, translation of these messages into detectable proteins and their subcellular localization depends on cell culture conditions. Manipulation of oxygen concentration and FGF2 supplementation can modulate expression of some pluripotency related genes at the transcriptional, translational, and cellular localization level. Changing cell culture condition parameters led to expression of REX1, potentiation of expression of LIN28, translation of OCT4, SOX2, and NANOG, and translocation of these transcription factors to the cell nucleus. We also show that culture conditions affect the in vitro lifespan of dermal fibroblasts, nearly doubling the number of population doublings before the cells reach replicative senescence. Our results suggest that it is possible to induce and manipulate endogenous expression of stem cell genes in somatic cells without genetic manipulation, but this short-term induction may not be sufficient for acquisition of true pluripotency. Further investigation of the factors involved in inducing this response could lead to discovery of defined culture conditions capable of altering cell fate in vitro. This would alleviate the need for forced expression by transgenesis, thus eliminating the risk of mutagenic effects due to genetic manipulation.

Mouse embryonic stem cells (mESCs) have played a key role in the newly emerging fields of stem cell research. The traditional derivation and culture of mESCs have been based on the use of mouse embryonic fibroblasts (MEFs) treated with exogenous leukemia inhibitory factor (LIF). However, the rapid senescence of MEFs, coupled with the high cost of LIF, has significantly hampered the widespread use of mESCs in stem cell research. Thus, we present a novel exogenous LIF-free culture system for general mESCs applications, comprising fibroblast-like cells derived from the rabbit spleen (RSFs). We demonstrated that mESCs cultured on RSFs (mESCs-RSFs) maintained all mESC features after prolonged LIF-free culture, including alkaline phosphatase, cell surface markers (SSEA-1), molecular markers (OCT-4, NANOG, TERT, REX-1), karyotype, and pluripotency. The high expression level of both LIF and WNT3A in the RSFs may account for their ability to maintain mESCs without exogenous LIF. Moreover, this exogenous LIF-free culture system was verified to be of microbiological quality through analysis with electron transmission microscopy.

Multipotent mesenchymal stromal cells (MSC) are progenitor cells able to differentiate into several lineages including chondrocytes, and thus represent a suitable source of cells for cartilage engineering. However, the control of MSC differentiation to hypertrophy is a crucial step for the clinical application of MSC in cartilage repair where a stable chondrogenic phenotype without transition to terminal differentiation is the goal to achieve. This study aims at identifying new factors that may regulate this process. Using microarrays, we compared the transcriptional profiles of human MSC and MSC-derived chondrocytes obtained after culture in micropellets. After chondrogenesis induction, 676 genes were upregulated, among which five transcription factors not yet associated with chondrocyte differentiation of adult stem cells. These factors, in particular Foxo3A, are strongly expressed at day 21 and in mature chondrocytes. We investigated the role of Foxo3A using RNA interference. Our results revealed an important role of Foxo3A in the differentiation process of MSC toward chondrogenic fate, both in early and late stages. Indeed, stable Foxo3A knockdown tends to increase cell survival and decrease apoptosis, mainly in early stages of chondrogenesis. Importantly, we show that the loss of Foxo3A in MSC results in an increased expression level of markers specific for mature (aggrecan, collagen II) and hypertrophic (collagen X) chondrocytes. Therefore, our findings suggest that upregulation of Foxo3A over the course of chondrogenic differentiation plays a dual role, mainly inhibiting the differentiation process toward hypertrophy and promoting cell apoptosis.

To improve intersubspecies cloning efficiency, this paper provides six kinds of SCNT embryos with different nuclear-cytoplasmic relatedness to compare the relatedness on the cloning efficiency. Three kinds of SCNT embryos with different relatedness are produced by using Boer goat fibroblast cells as nuclear donors and oocytes of Sannen goat, crossbred F1 (Sannen goat x Boer goat) and Boer goat as cytoplast recipients. Four kinds of SCNT embryos with different relatedness are produced by using Sannen goat oocytes as recipients and fibroblast cells of Boer goat, crossbred F2 (crossbred F1 x Boer goat), crossbred F1, and Sannen goat as nuclear donors. Results show that no obvious differences were observed for preimplantation development of these SCNT embryos. However, different nuclear-cytoplasmic relatedness resulted in obvious differences for postimplantation development of these SCNT embryos. The relatedness is complementary: improving either cytoplasmic compatibility relatedness to nucleus or nuclear relatedness to cytoplast could reduce the gestation loss rate, and increase the birth rate of cloned intersubspecies embryos significantly. But a further amelioration of the relatedness did not improve the postimplantation development in direct proportion. These results suggested that close nuclear-cytoplasmic relatedness can improve the postimplantation development rate of cloned intersubspecies embryos.