Cloning Stem Cells最新文献

The immediate events of genomic reprogramming at somatic cell nuclear transfer (SCNT) are to high degree unknown. This study was designed to evaluate the nuclear and nucleolar changes during the first cell cycle. Bovine SCNT embryos were produced from starved bovine fibroblasts and fixed at 0.5, 1, 2, 3, 4, 8, 12, and 16 h postactivation (hpa). Parthenogenetic (PA) embryos were used as control. The SCNT and PA embryos were processed for lacmoid staining, autoradiography, transmission electron microscopy (TEM), and immunofluorescence localization of: upstream binding factor (UBF) and fibrillarin at 4 and 12 hpa. Likewise, starved and nonstarved fibroblasts were processed for autoradiography and TEM. The fibroblasts displayed strong transcriptional activity and active fibrillogranular nucleoli. None of the reconstructed embryos, however, displayed transcriptional activity. In conclusion, somatic cell nuclei introduced into enucleated oocytes displayed chromatin condensation, partial nuclear envelope breakdown, nucleolar desegregation and transcriptional quiescence already at 0.5 hpa. Somatic cell cytoplasm remained temporally attached to introduced nucleus and nucleolus was partially restored indicating somatic influence in the early SCNT phases. At 1-3 hpa, chromatin gradually decondensed toward the nucleus periphery and nuclear envelope reformed. From 4 hpa, the somatic cell nucleus gained a PN-like appearance and displayed NPBs suggesting ooplasmic control of development.

BMP-11/GDF-11 and Myostatin/GDF-8 are both members of the TGF-beta superfamily that can activate SMAD2/3 phosphorylation via the type I receptors ALK4, ALK5, or ALK7. We tested the ability of BMP-11 and Myostatin to promote self-renewal of human embryonic stem cells (hESC) under feeder-free and serum-free culture conditions in short term (1 week) and medium term cultures (10 weeks). We show that hESC cultured in serum-free medium supplemented with either 20 ng/mL Myostatin or 20 ng/mL BMP-11 maintain the colony and cellular morphology of undifferentiated hESC, maintain POU5f1, NANOG, TRA-1-60, and SSEA4 expression, and display increased SMAD2/3 phosphorylation, similar to hESC cultured in mouse embryonic fibroblast feeder-CM or 20 ng/mL Activin-A. The type I TGF-beta receptor inhibitor SB431542 totally inhibited the maintenance activity of both Myostatin or BMP-11 supplemented medium. Our data show that members of the TGF-beta superfamily, other than Activin-A and GDF3, are able to maintain hES cells in an undifferentiated state under feeder free conditions.

Agronomical applications of cloned livestock produced by somatic cell nuclear transfer (SCNT) have been authorized in the United States and the European Food Safety Authority published that there was no evidence of risks associated with the use of cloned animal in the breeding industry. Both assessments, however, underlined that complementary data are needed to update their conclusions. SCNT is associated with a high incidence of perinatal losses. After birth, cloned cattle appear to possibly present subtle immune defects, requiring extensive studies to be properly evidenced. Twenty-five cloned Holstein heifers from five distinct genotypes and their contemporary age- and sex-matched controls were compared. An extensive survey of leukocyte subsets was performed and the humoral and T-cell immune responses to exogenous antigens were studied. Cloned cattle presented a normal representation of leukocyte subsets. Functional immunity was not modified in cloned heifers, as they were able to raise an antibody response and to develop B and T cell-specific responses against the model antigen OVA (ovalbumin) and against a rotavirus vaccine as in controls. Thus, this extensive analysis supports previous data suggesting that cloned cattle have a normal immunity.

Embryonic stem cells (ESC) hold tremendous potential for therapeutic applications, including regenerative medicine, as well as for understanding basic mechanisms in stem cell biology. Since numerous experiments cannot be conducted in human ESC because of ethical or practical limitations, nonhuman primate ESC serve as invaluable clinically relevant models. The novel marmoset (Callithrix jacchus) ESC line cjes001 was characterized using different stem cell markers. The cells were stained positively with Oct4, SSEA-3, SSEA-4, Tra-1-60, Tra-1-81, and Sox-2 underscoring their status as undifferentiated ESC. ESC are typically grown on mouse embryonic fibroblasts (MEF) as feeder cells whose proliferation is arrested either by treatment with Mitomycin C or by gamma-irradiation. To assess the impact of these treatments on the ability of MEF to support the growth of undifferentiated ESC, we used an MTT assay to evaluate the cellular metabolic activity of growth arrested feeder cells. There was a significant (p < 0.02) difference in gamma-irradiated cells displaying a higher metabolic activity compared to Mitomycin C inactivation. Also we quantified 69 soluble factors in the supernatant of both Mitomycin-treated and gamma-irradiated MEF by bead-based multiplex analysis, and thus established a profile of MEF-secreted factors. The time course of secretion was analyzed by monitoring the supernatant at 0, 6, 12, and 24 h after changing the medium. Comparing gamma-irradiated and Mitomycin-treated MEF suggested higher amounts of some cytokines including FGF or SCF by the former. We also assessed whether the method of inactivation had an effect on growth kinetics and differentiation of primate ESC. There appeared to be a trend to a lower number of differentiated ESC colonies on the gamma-irradiated feeder cells, suggesting that this may be the preferable method of growth arrest.

Stable and full differentiation of pluripotent stem cells into functional beta-cells offers the potential to treat type I diabetes with a theoretically inexhaustible source of replacement cells. In addition to the difficulties in directed differentiation, progress toward an optimized and reliable protocol has been hampered by the complication that cultured cells will concentrate insulin from the media, thus making it difficult to tell which, if any, cells are producing insulin. To address this, we utilized a novel murine embryonic stem cell (mESC) research model, in which the green fluorescent protein (GFP) has been inserted within the C-peptide of the mouse insulinII gene (InsulinII-GFP). Using this method, cells producing insulin are easily identified. We then compared four published protocols for differentiating mESCs into beta-cells to evaluate their relative efficiency by assaying intrinsic insulin production. Cells differentiated using each protocol were easily distinguished based on culture conditions and morphology. This comparison is strengthened because all testing is performed within the same laboratory by the same researchers, thereby removing interlaboratory variability in culture, cells, or analysis. Differentiated cells were analyzed and sorted based on GFP fluorescence as compared to wild type cells. Each differentiation protocol increased GFP fluorescence but only modestly. None of these protocols yielded more than 3% of cells capable of insulin biosynthesis indicating the relative inefficiency of all analyzed protocols. Therefore, improved beta-cells differentiation protocols are needed, and these insulin II GFP cells may prove to be an important tool to accelerate this process.

Mouse and human embryonic stem (ES) cells are usually maintained in an undifferentiated state by coculture with mouse embryonic fibroblasts (MEFs) as feeder cells. In the case of mouse ES cells, addition of leukemia inhibitory factor (LIF) to culture media is also necessary to prevent cell differentiation. Here, we report the use of primary human amnion epithelial cells (hAECs) as feeder cells to culture mouse ES cells using our newly developed protocols. We found that mouse ES cells grown on hAECs express ES cell markers including FGF, Oct-4, Nanog, Sox-2, Rex, and TERT. Interestingly, the expression levels of these genes are three- to five fold higher on hAECs than on MEFs by quantitative real-time PCR. The quicker growing ES cells on hAECs showed a normal 19XY karyotype on passages 25, and ruled out the transformation of ES cells. Using flow cytometry analysis, we show that ES cells grown on hAECs have the same cell cycle distribution pattern as those on MEFs. Further, mouse ES cells cultured on hAECs for at least 20 passages retain the capability of teratoma formation in mice. Finally, we reveal that hAECs express highly LIF that allows for ES growth without the need of addition of commercially obtained LIF. Taken together, our data suggest that hAECs are suitable for mouse ES cell culture and may prove to be a useful alternative to MEFs for human ES cell culture.

The purpose of this study was to establish transgenic porcine embryonic stem (pES) cell lines that can stably express report gene. Established pES cell line at passage 44 was transfected with pAAV-hrGFP Control Plasmid by electroporation-mediated, viral vector-mediated, and liposome-mediated strategies. Although there were several pES colonies expressing green fluorescent protein (GFP) obtained from the retrovirus-mediated and liposome-mediated transfection methods, no stable GFP-expressing pES cell line was then derived. A total of 28 GFP-expressing pES cell colonies were obtained following electroporation with two DC pulses of 150 V/cm for 10 msec and three GFP-expressing pES (pES/GFP(+)) cell lines were established. These pES/GFP(+) cell lines stably expressed exogenous GFP and continuously proliferated in vitro for more than 90 passages in 20 months. They maintained normal karyotype of 36 + XX and typical characteristics of pluripotent stem cells, including expression of pluripotent markers Oct-4, AP, SSEA-4, TRA-1-60, and TRA-1-81, formation of embryoid bodies under suspension culture. They were able to differentiate in vitro into neural and cardiomyocytic lineage, respectively, under suitable induction. To our knowledge, there has been no report of establishing GFP-expressing pES cell lines. These novel pES/GFP(+) cell lines established in this study might serve as a nonrodent model and would benefit to the studies involving ES cell transplantation, cell replacement therapy, and tissue regeneration due to their traceable capacity.

The HOX family of genes plays a fundamental role in the morphogenesis of vertebrate embryonic cells. HOX genes are thought to be important for the regulation of stem cells. We investigated HOX gene expression in mesenchymal stem cells (MSCs) from human placentas. We isolated MSCs from human placentas and confirmed stemness by fluorescence-activated cell sorting (FACS) analysis and differentiation studies. Using reverse transcription PCR, mRNA expression of 39 Class I HOX genes was measured in the MSCs. The expression of HOXB6, C4, C8, C10, D3, D4, and D10 were measured by Western blot analysis. HOXC10 was expressed in 10 of 10 amnion-derived MSCs but in only 2 of 10 decidua-derived MSCs. HOXC4 and D10 were expressed in 100% of both amnion-derived MSCs and deciduas-derived MSCs. HOXD4 was silent in all amnion-derived MSCs and deciduas-derived MSCs (n = 10). HOX gene activation patterns might be a useful indicator for the detection of MSCs of different tissue origins. We demonstrated that HOXC10 is a gene that may discriminate between amnion-derived MSCs and decidua-derived MSCs.

There is renewed interest in using animal oocytes to reprogram human somatic cells. Here we compare the reprogramming of human somatic nuclei using oocytes obtained from animal and human sources. Comparative analysis of gene expression in morula-stage embryos was carried out using single-embryo transcriptome amplification and global gene expression analyses. Genomic DNA fingerprinting and PCR analysis confirmed that the nuclear genome of the cloned embryos originated from the donor somatic cell. Although the human-human, human-bovine, and human-rabbit clones appeared morphologically similar and continued development to the morula stage at approximately the same rate (39, 36, and 36%, respectively), the pattern of reprogramming of the donor genome was dramatically different. In contrast to the interspecies clones, gene expression profiles of the human-human embryos showed that there was extensive reprogramming of the donor nuclei through extensive upregulation, and that the expression pattern was similar in key upregulation in normal control embryos. To account for maternal gene expression, enucleated oocyte transcriptome profiles were subtracted from the corresponding morula-stage embryo profiles. t-Test comparisons (median-normalized data @ fc>4; p<0.005) between human in vitro fertilization (IVF) embryos and human-bovine or human-rabbit interspecies somatic cell transfer (iSCNT) embryos found between 2400 and 2950 genes that were differentially expressed, the majority (60-70%) of which were downregulated, whereas the same comparison between the bovine and rabbit oocyte profiles found no differences at all. In contrast to the iSCNT embryos, expression profiles of human-human clones compared to the age-matched IVF embryos showed that nearly all of the differentially expressed genes were upregulated in the clones. Importantly, the human oocytes significantly upregulated Oct-4, Sox-2, and nanog (22-fold, 6-fold, and 12-fold, respectively), whereas the bovine and rabbit oocytes either showed no difference or a downregulation of these critical pluripotency-associated genes, effectively silencing them. Without appropriate reprogramming, these data call into question the potential use of these discordant animal oocyte sources to generate patient-specific stem cells.