Anmin Lei

Characterization of mesenchymal stem cells (MSCs) from human fetal lung: Potential differentiation of germ cells

Pluripotent mesenchymal stem-like cell lines were established from lungs of 3-4 months old aborted fetus. The cells present the high ex vivo expansion potential of MSC, a typical fibroblast-like morphology and proliferate up to 15 passages without displaying clear changes in morphology. Immunological localization and flow cytometry analyses showed that these cells are positive for OCT4, c-Kit, CD11, CD29, CD44, telomerase, CD106, CD105, CD166, and SSEA1, weakly expression or negative for SSEA1, SSEA3, SSEA4, CD34, CD105 and CD106. These cells can give rise to the adipogenic as evidenced by accumulation of lipid-rich vacuoles within cells identified by Oil-red O when they were induced with 0.5 mM isobutylmethylxanthine, 200 microM indomethacin, 10(-6)M dexamethasone, and 10 microg/ml of insulin in high-glucose DMEM. Osteogenic lineage cells were generated in 0.1 microM dexamethasone, 50 microg/ml ascorbic acid, 10 mM beta-glycerophosphate, which are shaped as the osteoblastic morphology, expression of alkaline phosphatase (AP), and the formation of a mineralized extracellular matrix identified by Alizarin Red staining. Neural cells are observed when the cultures were induced with 2-mercapometal, which are positive for nestin, NF-100, MBP and GFAP. Additionally, embryoid bodies (EBs) and sperm like cells are obtained in vitro differentiation of these lung MSCs induced with 10(-5)M retinoic acid (RA). These results demonstrated that these MSCs are pluripotent and may provide an in vitro model to study germ-cell formation and also as a potential source of sperms for male infertility.

Derivation and characterization of human embryonic germ cells: serum-free culture and differentiation potential

This study examined the effects of a chemically defined culture medium supplement, knock-out serum replacement (KSR), on the growth and differentiation of human embryonic germ cells (hEgc) and found that the efficiency of the initial establishment of hEGC lines in KSR medium was significantly higher than in fetal calf serum (FCS) medium. The percentage of undifferentiated hEGC colonies growing in KSR medium was significantly higher than in FCS-based medium (P < 0.05). The hEGC colonies showed typical mouse embryonic germ cell-like morphology. They showed normal and stable diploid karyotype and expressed alkaline phosphatase (AP), stage-specific embryonic antigens (SSEA) and other specific markers of pluripotent cells. In addition, hEGC could form simple and cystic embryoid bodies (EB) that consisted of various cell types including neural, epithelial and rhythmically beating cardiac cells, even sperm-like and oocyte-like cells. Tumour-like outgrowths were formed in nude mice and found to contain a variety of cell types, including uterine epithelium, adipocytes, squamous tissue and skin structures. In conclusion, an appropriate serum-free culture system has been developed for the establishment of hEGC lines. This may provide an in-vitro model to study differentiation and can be used as a potential source of therapy for infertility and regenerative medicine.

Insulin–transferrin–selenium (ITS) improves maturation of porcine oocytes in vitro

The objective of this study was to determine if insulin-transferrin-selenium (ITS) promoted a nuclear and cytoplasmic maturation of porcine oocytes that better supports subsequent embryonic development. The rate of oocyte in vitro maturation (IVM) in an experimental group treated with hormones for 42 h was significantly increased compared with that in a control group without hormone treatment (47.8% vs. 11.7%, respectively, p < 0.05). Following reduction of the hormone treatment period from 42 h to 21 h, which included both the first 21 h period of hormones treatment (45.4%) and the second 21 h period of hormone treatment (44.8%), the rate of oocyte IVM was still higher than that of the control group (p < 0.05). To improve porcine oocyte nuclear maturation, 1% ITS was added to medium supplemented with hormones. The rate of nuclear maturation in the ITS-treated group was significantly higher than in the ITS-untreated group (78.6% vs. 54.4%, respectively, p < 0.05). ITS treatment also significantly reduced the per cent of oocytes with type I and type III cortical granule (CG) distribution, respectively, and significantly increased the per cent of oocytes with type II CG distribution (85.3%). These observations indicated that the synchronization rates of nuclear and ooplasmic maturation reached 67.04% (78.56 × 85.33%). In conclusion, the combination of modified Tissue Culture Medium-199 (mM199) + 10 ng/ml epidermal growth factor (EGF) + 10 IU/ml pregnant mare serum gonadotrophin (PMSG) + 10 IU/ml human chorion gonadotrophin (hCG) + 2.5 IU/ml follicle stimulating hormone (FSH) + 1% ITS is suitable for culturing porcine oocytes in vitro, and effectively enhances porcine oocyte nuclear and cytoplasmic maturation.

Pancreatic Islet-Like Clusters from Bone Marrow Mesenchymal Stem Cells of Human First-Trimester Abortus Can Cure Streptozocin-Induced Mouse Diabetes

Bone marrow mesenchymal stem cells (BMSCs) have been reported to possess low immunogenicity and cause immunosuppression of recipients when allografted. They can differentiate into insulin-producing cells and may be a valuable source for islet formation. However, the extremely low differentiating rate of adult BMSCs toward insulin-producing cells and the insufficient insulin secretion of the differentiated BMSCs in vitro prevent their clinical use in diabetes treatment. Little is known about the potential of cell replacement therapy with human BMSCs. Previously, we isolated and identified human first-trimester fetal BMSCs (hfBMSCs). Under a novel four-step induction procedure established in this study, the hfBMSCs effectively differentiated into functional pancreatic islet-like cell clusters that contained 62 ± 14% insulin-producing cells, expressed a broad gene profile related to pancreatic islet β-cell development, and released high levels of insulin (2.245 ± 0.222 pmol/100 clusters per 30 min) and C-peptide (2.200 ± 0.468 pmol/100 clusters per 30 min) in response to 25 mmol/L glucose stimulus in vitro. The pancreatic islet-like cell clusters normalized the blood glucose level of diabetic model mice for at least 9 weeks when xenografted; blood glucose levels in these mice rose abnormally again when the grafts were removed. Examination of the grafts indicated that the transplanted cells survived in recipients and produced human insulin and C-peptide in situ. These results demonstrate that hfBMSCs derived from a human first-trimester abortus can differentiate into pancreatic islet-like cell clusters following an established four-step induction. The insulin-producing clusters present advantages in cell replacement therapy of type 1 diabetic model mice.

The Four Reprogramming Factors and Embryonic Development in Mice

The transcription factors (Oct4, Sox2, c-Myc, and Klf4) play an important role in the generation of induced pluripotent stem cells. These factors are expressed in metaphase II oocytes and embryonic stem cells (ESCs). The mechanisms responsible for the reprogramming of ooplasm during nuclear transfer are expected to be associated with the four factors. Here, we show that different paternal genetic backgrounds are able to influence the in vitro development of parthenogenetic and cloned embryos. Using real- time polymerase chain reaction (PCR) we found that the expression level of Oct4 in oocytes was less than that of ESCs, whereas oocytes from KM x C3H females showed the highest expression level of Sox2 than the other strains tested or in G1 ESCs. c-Myc mRNA levels in oocytes from KM mice were greater than those found in ESCs or oocytes of KM x C3H mice. These data demonstrate that the expression of the four transcription factors was different among the oocytes, which may be a contributing factor for the different efficiencies of parthenogenesis and the development of cloned embryos in vitro.

Reconstruction of damaged corneal epithelium using Venus-labeled limbal epithelial stem cells and tracking of surviving donor cells

Limbal epithelial stem cells are responsible for the self-renewal and replenishment of the corneal epithelium. Although it is possible to repair the ocular surface using limbal stem cell transplantation, the mechanisms behind this therapy are unclear. To investigate the distribution of surviving donor cells in a reconstructed corneal epithelium, we screened a Venus-labeled limbal stem cell strain in goats. Cells were cultivated on denuded human amniotic membrane for 21 days to produce Venus-labeled corneal epithelial sheets. The Venus-labeled corneal epithelial sheets were transplanted to goat models of limbal stem cell deficiency. At 3 months post-surgery, the damaged corneal epithelia were obviously improved in the transplanted group compared with the non-transplanted control, with the donor cells still residing in the reconstructed ocular surface epithelium. Using Venus as a marker, our results indicated that the location and survival of donor cells varied, depending on the corneal epithelial region. Additionally, immunofluorescent staining of the reconstructed corneal epithelium demonstrated that many P63(+) cells were unevenly distributed among basal and suprabasal epithelial layers. Our study provides a new model, and reveals some of the mechanisms involved in corneal epithelial cell regeneration research.

H1foo is essential for in vitro meiotic maturation of bovine oocytes.

Oocyte-specific linker histone, H1foo, is localized on the oocyte chromosomes during the process of meiotic maturation, and is essential for mouse oocyte maturation. Bovine H1foo has been identified, and its expression profile throughout oocyte maturation and early embryo development has been established. However, it has not been confirmed if H1foo is indispensable during bovine oocyte maturation. Effective siRNAs against H1foo were screened in HeLa cells, and then siRNA was microinjected into bovine oocytes to down-regulate H1foo expression. H1foo overexpression was achieved via mRNA injection. Reverse transcription polymerase chain reaction (RT-PCR) results indicated that H1foo was up-regulated by 200% and down-regulated by 70%. Based on the first polar body extrusion (PB1E) rate, H1foo overexpression apparently promoted meiotic progression. The knockdown of H1foo significantly impaired bovine oocyte maturation compared with H1foo overexpression and control groups (H1foo overexpression = 88.7%, H1foo siRNA = 41.2%, control = 71.2%; P < 0.05). This decrease can be rescued by co-injection of a modified H1foo mRNA that has escaped from the siRNA target. However, the H1e (somatic linker histone) overexpression had no effect on PB1E rate when compared with the control group. Therefore we concluded that H1foo is essential for bovine oocyte maturation and its overexpression stimulates the process.

FSH is superior to eCG for promoting ovarian response in Chinese Bamei gilts.

The Bamei gilt is a Chinese native breed located in northwest China, which adapts to the extremely dry and cold environment and is distinguished for its excellent reproductive and maternal characters. To ensure sufficient numbers of embryos for transgenic and nuclear transfer research, hormonal induction of gilt estrus and superovulation may be necessary. The objective of this study was to compare the superovulation effects of equine chorionic gonadotropin (eCG, Group A) and FSH (Groups B-D) in Chinese Bamei gilts. The results show that though eCG could produce more corpora lutea (CL, 14.3) than the control (CL, 9.2), and the FSH treatments had significantly increased the number of CL compared with the eCG treatment. Within the different FSH protocols, the numbers of CL were significantly greater in Groups B (CL, 77.8) and C (CL, 66.8) than in Group D (CL, 42.7), however, ovarian cysts were observed in Groups B and C, but not in Group D. These data suggest that Group D (280 IU FSH) is a suitable protocol to facilitate the development of ovarian follicles and increase the number of useful embryos per gilt for embryos recovery. The optimal FSH protocol of superovulation in Bamei gilts appears to be: D13/100 IU, D14/80 IU, D15/60 IU, D16/40 IU plus prostaglandin (PG) 0.2mg, D17/hCG 1000 IU.