Efficient generation of transgene- and feeder-free induced pluripotent stem cells from human dental mesenchymal stem cells and their chemically defined differentiation into cardiomyocytes

Advance in stem cell research resulted in several processes to generate induced pluripotent stem cells (iPSCs) from adult somatic cells. In our previous study, the reprogramming of iPSCs from human dental mesenchymal stem cells (MSCs) including SCAP and DPSCs, has been reported. Herein, safe iPSCs were reprogrammed from SCAP and DPSCs using non-integrating RNA virus vector, which is an RNA virus carrying no risk of altering host genome. DPSCs- and SCAP-derived iPSCs exhibited the characteristics of the classical morphology with human embryonic stem cells (hESCs) without integration of foreign genes, indicating the potential of their clinical application. Moreover, induced PSCs showed the capacity of self-renewal and differentiation into cardiac myocytes. We have achieved the differentiation of hiPSCs to cardiomyocytes lineage under serum and feeder-free conditions, using a chemically defined medium CDM3. In CDM3, hiPSCs differentiation is highly generating cardiomyocytes. The results showed this protocol produced contractile sheets of up to 97.2% TNNT2 cardiomyocytes after purification. Furthermore, derived hiPSCs differentiated to mature cells of the three embryonic germ layers in vivo and in vitro of beating cardiomyocytes. The above whole protocol enables the generation of large scale of highly pure cardiomyocytes as needed for cellular therapy.     

Production of calves by transfer of nuclei from cultured somatic cells obtained from Japanese black bulls

We investigated the possibility of producing calves from transferable bovine embryos obtained by nuclear transfer using somatic cell-derived cell lines. Muscle cells obtained from 2 Japanese Black bulls were dispersed in Hank's solution supplemented with collagenase Type-I. The separated muscle cells were cultured in Dulbecco's Modified Eagle's medium (D-MEM) supplemented with 10% fetal bovine serum (FBS) at 39 degrees C in an atmosphere of 5% CO2 in air. Cells were passaged at least 4 times, and for 5 d prior to nuclear transfer they (donor cells: karyoplasts) were cultured in D-MEM supplemented with 0.5% FBS (to induce quiescence) or 10% FBS. Recipient oocytes were produced by in vitro culture of bovine oocytes that were obtained at a slaughterhouse and then enucleated in modified phosphate buffered saline supplemented with cytochalasin B. Embryos were reconstructed by 3 protocols using karyoplasts cultured in the medium with 0.5% FBS. 1) Group A: recipient oocytes (cytoplasts; n = 157) were treated with Ca ionophore A 23187, ethanol and cycloheximide, and then a karyoplast was fused to an activated cytoplast. 2) Group B: karyoplasts were transferred to cytoplasts (n = 117), and the couplets were treated with electric stimulation and then Ca ionophore A 23187 and cycloheximide. 3) Group C: cytoplasts (n = 104) were cultured for a further 12 h before fusion, and then the couplets were treated with electric stimulation and cycloheximide. 4) Group D: in addition to the above 3 groups, karyoplasts cultured in the medium with 10% FBS were transferred to recipient cytoplasts (n = 137) and treated as in Protocol 2. Reconstructed embryos were cultured in modified CR1aa for 8 d, and the development of embryos was assessed. In total 73 blastocysts were obtained, and the frequency of development to the blastocyst stage in Group A (2.5%) was lower than that of Groups B, C and D (20.5, 18.3 and 19.0%, respectively; P < 0.01). Of these the sex of 21 blastocysts was determined by rapid Y-chromosome detection assay, and all were male, suggesting that nuclear replacement had been achieved successfully. When 26 blastocysts were transferred to 20 recipient cows, 8 of them became pregnant; 4 cows subsequently aborted about 60 d after embryo transfer while the remaining 4 cows calved. These results indicate that reconstructed embryos obtained by nuclear transfer of muscle cell-derived cell lines can develop to the blastocyst stage, and some are sufficiently competent to develop to term. Particularly important was the finding that special culture protocols for somatic cells prior to nuclear transfer were not necessary in our system.     

Nuclear lamin antigen and messenger RNA expression in bovine in vitro produced and nuclear transfer embryos

The nuclear lamina is a complex meshwork of nuclear lamin filaments that lies on the interface of the nuclear envelope and chromatin and is important for cell maintenance, nucleoskeleton support, chromatin remodeling, and protein recruitment to the inner nucleolus. Protein and mRNA patterns for the major nuclear lamins were investigated in bovine in vitro fertilized (IVF) and nuclear transfer embryos. Expression of lamins A/C and B were examined in IVF bovine germinal vesicle (GV) oocytes, metaphase II oocytes, zygotes, 2-cell, 8-cell, 16-32-cell embryos, morulae, and blastocysts (n = 10). Lamin A/C was detected in 9/10 immature oocytes, 10/10 zygotes, 8/10 2-cell embryos, 4/10 morulae, 10/10 blastocysts but absent during the maternal embryonic transition. Lamin B was ubiquitously expressed during IVF preimplantation development but was only detected in 4/10 GV oocytes. Messenger RNA expression confirms that the major lamins, A/C and B1 are expressed throughout preimplantation development and transcribed by the embryo proper. Lamin A/C and B expression were observed (15 min, 30 min, 60 min, 120 min) following somatic cell nuclear transfer using adult fibroblasts and at the 2-cell, 8-cell, 16-32-cell, morula and blastocyst stage (n = 5). Altered expression levels and localization of nuclear lamins A/C and B was determined in nuclear transfer embryos during the first 2 hr post fusion, coincidental with only partial nuclear envelope breakdown as well as during the initial cleavage divisions, but was restored by the morula stage. This mechanical and molecular disruption of the nuclear lamina provides key evidence for incomplete nuclear remodeling and reprogramming following somatic cell nuclear transfer.     

Nuclear transfer-mediated rescue of the nuclear genome of nonviable mouse cells frozen without cryoprotectant

Nuclear transfer (NT) provides an opportunity for clonal amplification of a nuclear genome of interest. Here, we report NT-mediated reprogramming with frozen mouse cells that were nonviable because they were frozen at -80 degrees C for up to 342 days without a cryoprotectant. We derived eight embryonic stem (ES) cell lines from cloned blastocysts by conventional NT procedure and five ntES (nuclear transfer embryonic stem) cell lines by a modified NT procedure in which a whole cell instead of a nucleus was injected into an enucleated oocyte. Chromosome analysis revealed that 12 of 13 ntES cell lines have normal karyotypes. On injection of ntES cells into tetraploid blastocysts to generate clonal mice that are nearly completely ntES-cell derived, live pups were obtained; four clonal mice survived until adulthood. On injection of ntES cells into diploid blastocysts, chimeric mice with a high somatic ES cell contribution were generated; germ-line transmission was obtained. Our findings indicate that chromosome stability and genomic integrity can be maintained in mouse somatic cells after freezing without cryoprotection and that NT and ES cell techniques can rescue the genome of these cells.     

Genetic reprogramming of lactate dehydrogenase, citrate synthase, and phosphofructokinase mRNA in bovine nuclear transfer embryos produced using bovine fibroblast cell nuclei

Adult animal cloning has progressed to allow the production of offspring cloned from adult cells, however many cloned calves die prenatally or shortly after birth. This study examined the expression of three important metabolic enzymes, lactate dehydrogenase (LDH), citrate synthase, and phosphofructokinase (PFK), to determine if their detection in nuclear transfer (NT) embryos mimics that determined for in vitro produced embryos. A day 40 nuclear transfer produced fetus derived from an adult cell line was collected and fetal fibroblast cultures were established and maintained. Reconstructed NT embryos were then produced from this cell line, and RT-PCR was used to evaluate mRNA reprogramming. All three mRNAs encoding these enzymes were detected in the regenerated fetal fibroblast cell line. Detection patterns were first determined for IVF produced embryos (1-cell, 2-cell, 6-8 cell, morula, and blastocyst stages) to compare with their detection in NT embryos. PFK has three subunits: PFK-L, PFK-M, and PFK-P. PFK-L and PFK-P were not detected in bovine oocytes. PFK subunits were not detected in 6-8 cell embryos but were detected in blastocysts. Results from NT embryo RT-PCR demonstrated that PFK was not detected in 8-cell NT embryos but was detected in NT blastocysts indicating that proper nuclear reprogramming had occurred. Citrate synthase was detected in oocytes and throughout development to the blastocyst stage in both bovine IVF and NT embryos. LDH-A and LDH-B were detected in bovine oocytes and in all stages of IVF and NT embryos examined up to the blastocyst stage. A third subunit, LDH-C was not detected at the blastocyst stage in IVF or NT embryos but was detected in all earlier stages and in mature oocytes. In addition, LDH-C mRNA was detected in gonad isolated from the NT and an in vivo produced control fetus. These results indicate that the three metabolic enzymes maintain normal expression patterns and therefore must be properly reprogrammed following nuclear transfer.     

家畜体细胞克隆中核重编程机理研究进展

体细胞克隆在绵羊、山羊、牛、猪等家畜中获得了成功,但目前的克隆效率非常低。克隆效率低使家畜体细胞克隆技术在畜牧业生产及其他领域的应用受到极大的限制,问题的根源在于对体细胞克隆中核重编程的分子机理缺乏了解。供体细胞核移入去核的卵母细胞后,必须经过后成表观遗传修饰的重编程,从而恢复供体细胞核的全能性,才能保证重构胚的正常发育及个体的正常生长。本文从移植核的重构、DNA甲基化总体改变、组蛋白修饰、X染色体失活、端粒长度和端粒酶活性恢复、印迹基因及其他与发育相关基因的表达及核重编程的影响因素等几个方面探讨了体细胞克隆中的核重编程机理,为克隆效率提高的方法研究提供理论依据。     

Methylation reprogramming and chromosomal aneuploidy in in vivo fertilized and cloned rabbit preimplantation embryos

Active demethylation of the paternal genome but not of the maternal genome occurs in fertilized mouse, rat, pig, and bovine zygotes. To study whether this early demethylation wave is important for embryonic development, we have analyzed the global methylation patterns of both in vivo-fertilized and cloned rabbit embryos. Anti-5-methylcytosine immunofluorescence of in vivo-fertilized rabbit embryos revealed that the equally high methylation levels of the paternal and maternal genomes are largely maintained from the zygote up to the 16-cell stage. The lack of detectable methylation changes in rabbit preimplantation embryos suggests that genome-wide demethylation is not an obligatory requirement for epigenetic reprogramming. The methylation patterns of embryos derived from fibroblast and cumulus cell nuclear transfer were similar to those of in vivo-fertilized rabbit embryos. Fluorescence in situ hybridization with chromosome-specific BACs demonstrated significantly increased chromosomal aneuploidy rates in cumulus cell nuclear transfer rabbit embryos and embryos derived from nuclear transfer of rabbit fibroblasts into bovine oocytes compared with in vivo-fertilized rabbit embryos. The incidence of chromosomal abnormalities was correlated with subsequent developmental failure. We propose that postzygotic mitotic errors are one important explanation of why mammalian cloning often fails.     

体细胞重编程为多能干细胞的研究进展

体细胞通过重编程转变成其他类型的细胞,在再生医学方面具有重要的应用前景。细胞重编程的方法主要有体细胞核移植、细胞融合、细胞提取物诱导、限定因子诱导等,这些方法可以不同程度地改变细胞命运。最近,限定因子诱导的多能干细胞（induced pluripotent stem cell。iPS）为重编程提供了一种崭新的方法,不仅可以避免伦理争议,还提供了一种更为便利的技术,为再生医学开辟了新的天地;同时,iPS技术为研究基因表达调控、蛋白质互作、机体生长发育等提供了一个非常重要的研究手段。本文主要论述了体细胞重编程的方法及iPS细胞的进展、面临的问题和应用前景。     

体细胞核移植后表观遗传重编程的异常及其修复

体细胞核移植(Somatic cell nuclear transfer, SCNT)是指将高度分化的体细胞移入到去核的卵母细胞中发育并最终产生后代的技术。然而, 体细胞克隆的总体效率仍然处于一个较低的水平, 主要原因之一是由于体细胞供体核不完全的表观遗传重编程, 包括DNA甲基化、组蛋白乙酰化、基因组印记、X染色体失活和端粒长度等修饰出现的异常。使用一些小分子化合物以及Xist基因的敲除或敲低等方法能修复表观遗传修饰错误, 辅助供体核的重编程, 从而提高体细胞克隆效率, 使其更好地应用于基础研究和生产实践。文章对体细胞核移植后胚胎发育过程中出现的异常表观遗传修饰进行了综述, 并着重论述了近年来有关修复表观遗传错误的研究进展。     

Bovine oocyte cytoplasm supports nuclear remodeling but not reprogramming of murine fibroblast cells

Nuclear transfer (NT) is used to elucidate fundamental biological issues such as reversibility of cell differentiation and interactions between the cytoplasm and nucleus. To obtain an insight into interactions between the somatic cell nucleus and oocyte cytoplasm, nuclear remodeling and gene expression were compared in bovine oocytes that had received nuclei from bovine and mouse fibroblast cells. While the embryos that received nuclei from bovine fibroblast cells developed into blastocysts, those that received nuclei from mouse fibroblasts did not develop beyond the 8-cell stage. Similar nuclear remodeling procedures were observed in oocytes reconstructed with mouse and bovine fibroblast cells. Foreign centrosomes during NT were introduced into embryos reconstructed with both fibroblast cell types. A number of housekeeping mouse genes (hsp70, bax, and glt-1) were abnormally expressed in embryos that had received nuclei from mouse fibroblast cells. However, development-related genes, such as Oct-4 and E-cad, were not expressed. The results collectively suggest that the bovine oocyte cytoplasm supports nuclear remodeling, but not reprogramming of mouse fibroblast cells.     

Oxamflatin significantly improves nuclear reprogramming, blastocyst quality, and in vitro development of bovine SCNT embryos

Aberrant epigenetic nuclear reprogramming results in low somatic cloning efficiency. Altering epigenetic status by applying histone deacetylase inhibitors (HDACi) enhances developmental potential of somatic cell nuclear transfer (SCNT) embryos. The present study was carried out to examine the effects of Oxamflatin, a novel HDACi, on the nuclear reprogramming and development of bovine SCNT embryos in vitro. We found that Oxamflatin modified the acetylation status on H3K9 and H3K18, increased total and inner cell mass (ICM) cell numbers and the ratio of ICM∶trophectoderm (TE) cells, reduced the rate of apoptosis in SCNT blastocysts, and significantly enhanced the development of bovine SCNT embryos in vitro. Furthermore, Oxamflatin treatment suppressed expression of the pro-apoptotic gene Bax and stimulated expression of the anti-apoptotic gene Bcl-XL and the pluripotency-related genes OCT4 and SOX2 in SCNT blastocysts. Additionally, the treatment also reduced the DNA methylation level of satellite I in SCNT blastocysts. In conclusion, Oxamflatin modifies epigenetic status and gene expression, increases blastocyst quality, and subsequently enhances the nuclear reprogramming and developmental potential of SCNT embryos.     

High developmental rates of vitrified bovine oocytes following parthenogenetic activation, in vitro fertilization, and somatic cell nuclear transfer

Successful cryopreservation of mammalian oocytes would provide a steady source of materials for nuclear transfer and in vitro embryo production. Our goal was to develop an effective vitrification protocol to cryopreserve bovine oocytes for research and practice of parthenogenetic activation, in vitro fertilization, and nuclear transfer. Bovine oocytes matured in vitro were placed in 4% ethylene glycol (EG) in TCM 199 plus 20% fetal bovine serum (FBS) at 39 degrees C for 12-15 min, and then transferred to a vitrification solution (35% EG, 5% polyvinyl-pyrrolidone, 0.4 M trehalose in TCM 199 and 20% FBS). Oocytes were vitrified in microdrops on a precooled (-150 degrees C) metal surface (solid-surface vitrification). The vitrified microdrops were stored in liquid nitrogen and were either immediately thawed or were thawed after storage for 2-3 wk. Surviving oocytes were subjected to 1) parthenogenetic activation, 2) in vitro fertilization, or 3) nuclear transfer with cultured adult fibroblast cells. Treated oocytes were cultured in KSOM containing BSA or FBS for 9 to 10 days. Embryo development rates were recorded daily and morphologically high-quality blastocysts were cryopreserved for nuclear transfer-derived embryos at Day 7 or Day 8 of culture. Immediate survival of vitrified/thawed oocytes varied between 77% and 86%. Cleavage and blastocyst development rates of vitrified oocytes following in vitro fertilization or activation were lower than those of the controls. For nuclear transfer, however, vitrified oocytes supported embryonic development as equally well as fresh oocytes.     

Differential cytoplast requirement for embryonic and somatic cell nuclear transfer in cattle

Effective activation of a recipient oocyte and its compatibility with the nuclear donor are critical to the successful nuclear reprogramming during nuclear transfer. We designed a series of experiments using various activation methods to determine the optimum activation efficiency of bovine oocytes. We then performed nuclear transfer (NT) of embryonic and somatic cells into cytoplasts presumably at G1/S phase (with prior activation) or at metaphase II (MII, without prior activation). Oocytes at 24 hr of maturation in vitro were activated with various combinations of calcium ionophore A23187 (A187) (5 microM, 5 min), electric pulse (EP), ethanol (7%, 7 min), cycloheximide (CHX) (10 micro g/ml, 6 hr), and then cultured in cytochalasin D (CD) for a total of 18 hr. Through a series of experiments (Exp. 1-4), an improved activation protocol (A187/EP/CHX/CD) was identified and used for comparison of NT efficiency of embryonic versus somatic donor cells (Exp. 5). When embryonic cells from morula and blastocysts (BL) were used as nuclear donors, a significantly higher rate of blastocyst development from cloned embryos was obtained with G1/S phase cytoplasts than with MII-phase cytoplasts (36 vs. 11%, P < 0.05). In contrast, when skin fibroblasts were used as donor cells, the use of an MII cytoplast (vs. G1/S phase) was imperative for blastocyst development (30 vs. 6%, P < 0.05). Differential staining showed that parthenogenetic, embryonic, and somatic cloned BL contained 26, 29, and 33% presumptive inner cell mass (ICM) cells, respectively, which is similar to that of frozen-thawed in vivo embryos at a comparable developmental stage (23%). These data indicate that embryonic and somatic nuclei require different recipient cytoplast environment for remodeling/ reprogramming, and this is likely due to the different cell cycle stage and profiles of molecular differentiation of the transferred donor nuclei.     

体细胞核移植诱导的表观遗传学变化

体细胞核移植技术是指将一个分化的体细胞核置入去核的卵母细胞中,并发育产生与供体细胞遗传背景一致的克隆后代的技术。目前,世界上通过体细胞核移植技术已经产生了许多的克隆动物。但克隆过程中还存在着很多问题,比如,克隆效率太低、克隆个体常伴有表型异常和早亡等,从而使该技术应有的应用潜力不能得到充分的发挥。体细胞表观遗传学重编程的不完全或紊乱是造成核移植诸多问题的主要原因。近十多年来,人们对体细胞核移植后的重编程进行了广泛的研究,其核心内容包括核及核外结构的重塑、DNA甲基化模式的重建、基因印迹和x染色体失活、组蛋白乙酰化模式的重建、端粒长度恢复等,以期能够对其重编程加以人为干预,从而提高动物克隆效率。本文拟对体细胞核移植诱导的重编程研究进展加以综述,希望对体细胞重编程机制的阐明有所启发。     

Vitrification of immature and mature equine and bovine oocytes in an ethylene glycol, ficoll and sucrose solution using open-pulled straws

Studies were conducted to compare viability of immature and mature equine and bovine oocytes vitrified in ethylene glycol. Ficoll using open-pulled straws. Oocytes from slaughterhouse ovaries (N=50/group) with >2 layers of compact cumulus cells were vitrified immediately after collection (immature groups) or vitrified after 36 to 40 (equine) or 22 to 24 (bovine) h of maturation (mature groups). Immature oocytes were matured after thawing. Before vitrification, oocytes were exposed to TCM-199 + 10 FCS + 2.5 M ethylene glycol + 18% Ficoll + 0.5 M sucrose (EFS) for 30 sec and then to 5 M ethylene glycol in EFS for 25 to 30 sec at 37 degrees C. Oocytes were loaded into straws in approximately 2 microL of cryoprotectant and plunged directly into LN2. Warming straws and dilution of cryoprotectant was at 37 degrees C in TCM-199 + 10% FCS + 0.25 M sucrose for 1 min and then TCM-199 + 10% FCS + 0.15 M sucrose for 5 min. Non-vitrified oocytes undergoing the same maturation protocol for both species were used as controls. Oocytes were stained with orcein for nuclear maturation and live/dead status was determined using Hoechst 33342. Maturation of oocytes to MII after thawing was similar (P>0.05) among groups within species. All equine treatment groups had lower (P<0.01) maturation rates than bovine groups. Live/dead status did not differ among vitrification treatments within species. The percentage of oocytes that survived and reached MII did not differ (P>0.05) within treatment groups of each species. Rates of mature cortical granule distribution did not differ (P>0.05) within species; however, more bovine oocytes (P<0.05) had mature cortical granule distribution and nuclear maturation than equine oocytes. When concurrent cortical granule distribution and nuclear maturation were examined, there was no difference within species; however, only 30% of equine oocytes had nuclear and cytoplasmic maturation compared with 70% of bovine oocytes (P<0.05). In summary, both immature and mature equine and bovine oocytes survived cryopreservation using vitrification in open-pulled straws. However, survival rates were lower for equine than for bovine oocytes.