Improved development of ICR mouse 2-cell embryos by the addition of amino acids to a serum-, phosphate- and glucose-free medium

This study was conducted to evaluate how exogenous amino acids could affect preimplantation development of ICR mouse embryos. Two-cell embryos collected from naturally mated mice were cultured in amino acid-, glucose- and phosphate-free preimplantation (P)-1 medium. In Experiments 1, 19 amino acids (aa; 1% and 0.5% of MEM essential and nonessential amino acid solutions, respectively) were added to P-1 medium supplemented with either fatty acid-free bovine serum albumin (BSA; 3 mg/mL) or human follicular fluid (hFF; 10%). Regardless of BSA or hFF addition, embryo development to the morula (84 to 86% vs. 97 to 100%) and the blastocyst (54% vs. 93 to 94%) stages was significantly (P<0.05) enhanced by the addition of aa compared with no addition. In Experiment 2, the cell number of blastomeres and inner cell mass (ICM) cells in blastocysts and the ratio of ICM cell to trophectodermal cell (TE) were evaluated after aa addition. In both BSA- and hFF-containing P-1 medium, a significant increase in total blastomere number were found after aa addition (47 to 52 vs. 62 to 63 cells) compared with no addition. However, the ICM/TE ratio was not significantly affected by aa supplementation in both media, while ICM cell number was greatly increased after aa addition in hFF-containing medium (12 vs. 17 cells). When blastocysts were further cultured up to 162 hr post-hCG injection, development to the hatched blastocyst stage was significantly promoted by aa addition (0% vs. 11 to 20%) in both BSA- and hFF-containing media. In conclusion, aa significantly promote the preimplantation development to the hatched blastocyst stage and such effect mainly exerted on supporting blastomere proliferation

Alpha-1,3-galactosyltransferase-deficient miniature pigs produced by serial cloning using neonatal skin fibroblasts with loss of heterozygosity

Objective Production of alpha-1,3-galactosyltransferase (αGT)-deficient pigs is essential to overcome xenograft rejection in pig-to-human xenotransplantation. However, the production of such pigs requires a great deal of cost, time, and labor. Heterozygous αGT knockout pigs should be bred at least for two generations to ultimately obtain homozygote progenies. The present study was conducted to produce αGT-deficient miniature pigs in much reduced time using mitotic recombination in neonatal ear skin fibroblasts. Methods Miniature pig fibroblasts were transfected with αGT gene-targeting vector. Resulting gene-targeted fibroblasts were used for nuclear transfer (NT) to produce heterozygous αGT gene-targeted piglets. Fibroblasts isolated from ear skin biopsies of these piglets were cultured for 6 to 8 passages to induce loss of heterozygosity (LOH) and treated with biotin-conjugated IB4 that binds to galactose-α-1,3-galactose, an epitope produced by αGT. Using magnetic activated cell sorting, cells with monoallelic disruption of αGT were removed. Remaining cells with LOH carrying biallelic disruption of αGT were used for the second round NT to produce homozygous αGT gene-targeted piglets. Results Monoallelic mutation of αGT gene was confirmed by polymerase chain reaction in fibroblasts. Using these cells as nuclear donors, three heterozygous αGT gene-targeted piglets were produced by NT. Fibroblasts were collected from ear skin biopsies of these piglets, and homozygosity was induced by LOH. The second round NT using these fibroblasts resulted in production of three homozygous αGT knockout piglets. Conclusion The present study demonstrates that the time required for the production of αGT-deficient miniature pigs could be reduced significantly by postnatal skin biopsies and subsequent selection of mitotic recombinants. Such procedure may be beneficial for the production of homozygote knockout animals, especially in species, such as pigs, that require a substantial length of time for breeding

Cyclic Stretch Promotes Cellular Reprogramming Process through Cytoskeletal‐Nuclear Mechano‐Coupling and Epigenetic Modification

Abstract Advancing the technologies for cellular reprogramming with high efficiency has significant impact on regenerative therapy, disease modeling, and drug discovery. Biophysical cues can tune the cell fate, yet the precise role of external physical forces during reprogramming remains elusive. Here the authors show that temporal cyclic‐stretching of fibroblasts significantly enhances the efficiency of induced pluripotent stem cell (iPSC) production. Generated iPSCs are proven to express pluripotency markers and exhibit in vivo functionality. Bulk RNA‐sequencing reveales that cyclic‐stretching enhances biological characteristics required for pluripotency acquisition, including increased cell division and mesenchymal‐epithelial transition. Of note, cyclic‐stretching activates key mechanosensitive molecules (integrins, perinuclear actins, nesprin‐2, and YAP), across the cytoskeletal‐to‐nuclear space. Furthermore, stretch‐mediated cytoskeletal‐nuclear mechano‐coupling leads to altered epigenetic modifications, mainly downregulation in H3K9 methylation, and its global gene occupancy change, as revealed by genome‐wide ChIP‐sequencing and pharmacological inhibition tests. Single cell RNA‐sequencing further identifies subcluster of mechano‐responsive iPSCs and key epigenetic modifier in stretched cells. Collectively, cyclic‐stretching activates iPSC reprogramming through mechanotransduction process and epigenetic changes accompanied by altered occupancy of mechanosensitive genes. This study highlights the strong link between external physical forces with subsequent mechanotransduction process and the epigenetic changes with expression of related genes in cellular reprogramming, holding substantial implications in the field of cell biology, tissue engineering, and regenerative medicine

Increased caveolin-1, a cause for the declined adipogenic potential of senescent human mesenchymal stem cells

Mesenchymal stem cell (MSC) has drawn much attention in the aspect of tissue renewal and wound healing because of its multipotency. We initially observed that bone marrow-derived human MSCs (hMSCs) divided poorly and took flat and enlarged morphology after expanded in culture over a certain number of cell passage, which resembled characteristic features of senescent cells, well-studied in human diploid fibroblasts (HDFs). More interestingly, adipogenic differentiation potential of hMSCs sharply declined as they approached the end of their proliferative life span. In this study, altered hMSCs were verified to be senescent by their senescence-associated beta-galactosidase (SA-beta-gal) activity and the increased expression of cell cycle regulating proteins (p16(INK4a), p21(Waf1) and p53). Similar as in HDFs, basal phosphorylation level of ERK was also significantly increased in senescent hMSCs, implying altered signal paths commonly shared by the senescent cells. Insulin, a major component of adipogenesis inducing medium, did not phosphorylate ERK 1/2 more in senescent hMSCs after its addition whereas it did in young cells. In senescent hMSCs, we also found a significant increase of caveolin-1 expression, previously reported as a cause for the attenuated response to growth factors in senescent HDFs. When we overexpressed caveolin-1 in young hMSC, not only insulin signaling but also adipogenic differentiation was significantly suppressed with down-regulated PPARgamma2. These data indicate that loss of adipogenic differentiation potential in senescent hMSC is mediated by the over-expression of caveolin-1