Association between mitochondrial DNA haplotype compatibility and increased efficiency of bovine intersubspecies cloning

Reconstructed embryos derived from intersubspecies somatic cell nuclear transfer(SCNT) have poorer developmental potential than those from intrasubspecies SCNT.Based on our previous study that Holstein dairy bovine(HD) mitochondrial DNA(mtDNA) haplotype compatibility between donor karyoplast and recipient cytoplast is crucial for SCNT embryo development,we performed intersubspecies SCNT using HD as donor karyoplast and Luxi yellow heifer(LY) as recipient cytoplast according to mtDNA haplotypes determined...     

Association between mitochondrial DNA haplotype compatibility and increased efficiency of bovine intersubspecies cloning

Reconstructed embryos derived from intersubspecies somatic cell nuclear transfer (SCNT) have poorer developmental potential than those from intrasubspecies SCNT. Based on our previous study that Holstein dairy bovine (HD) mitochondrial DNA (mtDNA) haplotype compatibility between donor karyoplast and recipient cytoplast is crucial for SCNT embryo development, we performed intersubspecies SCNT using HD as donor karyoplast and Luxi yellow heifer (LY) as recipient cytoplast according to mtDNA haplotypes determined by polymerase chain reactionrestriction fragment length polymorphism (PCR-RFLP) analysis. The results demonstrated that intersubspecies mtDNA homotype SCNT embryos had higher pre- and post-implantation developmental competence than intrasubspecies mtDNA heterotype embryos as well as improved blastocyst reprogramming status, including normal H3K9 dimethylation pattern and promoter hypomethylation of pluripotent genes such as Oct4 and Sox2, suggesting that intersubspecies SCNT using LY oocytes maintains HD cloning efficiency and may reprogram HD nuclei to develop into a normal cloned animal ultimately. Our results indicated that karyoplast-cytoplast interactions and mtDNA haplotype compatibility may affect bovine intersubspecies SCNT efficiency. This study on bovine intersubspecies SCNT is valuable for understanding the mechanisms of mtDNA haplotype compatibility between karyoplast and cytoplast impacting the bovine SCNT efficiency, and provides an alternative and economic resource for HD cloning.     

Effect of cytoplast on the development of inter-subspecies nuclear transfer reconstructed goat embryo

The aim of this study was to investigate effect of cytoplast on the development competence of reconstructed embryos derived from inter-subspecies somatic cell nucleus transfer (SCNT). First, the development potency of reconstructed embryos produced by transferring Boer goat fibroblast cell nucleus of different ages into enucleated Sannen goat ova was evaluated in order to determine which age of nuclear donor is favorable for the reconstructed embryos development. Secondly, the another component of reconstructed embryos, "cytoplast," was evaluated by comparing the effect of ovum cytoplast derived from Sannen male symbol x Boer female symbol descendant on the reconstructed embryos development to that of Sannen goat ovum cytoplast. The results revealed that the development rate of the reconstructed embryos derived from 2 months old Boer goat somatic cells was the highest, their gestation rate was up to 50%, and one viable male offspring was obtained. The cytoplast derived from the crossbreeding goats improves the development competence of reconstructed embryos, which birth rate was 5.5%. The genetic identification of offspring by using PCR-SSCP analysis confirmed that these cloned kids were derived from the donor. The results above reveal that the cytoplast of Sannen goat ovum could induce the dedifferentiation of somatic cell nuclei derived from Boer goat, but the reprogramming process of these reconstructed embryos seems incomplete, probably due to some incorrect processes happened after implantation. Relatedness components of nucleus donor in cytoplast of the crossbreeding goat may be helpful to induce the dedifferentiation of somatic cell nuclei completely and improve the development competence of the reconstructed embryos.     

Cytoplast containing reprogramming-related factors from human embryonic stem cells arrested at metaphase

Generating pluripotent stem cells directly from a patient's somatic cells is one of the major methods to avoid rejection in future regenerative medicine. It is reported that human embryonic stem cells (hESCs) are able to reprogram the nuclei of fully differentiated human somatic cells, apparently conferring on them a pluripotent state. However, the ability of the cytoplasts from enucleated hESCs to reprogram somatic cells causes much controversy. Here we detect the location of pluripotency-related factors such as Oct4/Nanog/Sox2 in the hESCs at division and non-division stage and obtain the cytoplasts of hESCs by centrifugation. We demonstrate for the first time that the cytoplast from hESCs arrested at the division phase of cell the cycle contains the reprogramming factors and this kind of cytoplast can be obtained through gradient centrifugation. These give us direct proof of the possibility of reprogramming somatic cell using cytoplast of hESCs and make this a possible method for getting patient-specific pluripotent cells without extrinsic DNA introduction.     

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.     

Coexistence of Bos taurus and B. indicus mitochondrial DNAs in nuclear transfer-derived somatic cattle clones

We investigated the mitochondrial DNA (mtDNA) composition in one of the largest adult somatic mammalian clones (n = 20) reported so far. The healthy cloned cattle were derived from nuclear transfer of an identical nuclear genetic background (mural granulosa donor cells including surrounding cytoplasm) into enucleated oocytes with either Bos indicus or B. taurus mtDNA. Here we report the first cases of coexisting mtDNAs of two closely related subspecies following nuclear transfer. Heteroplasmy (0.6-2.8%) was found in 4 out of 11 cross-subspecies cloned cattle. Quantitation was performed using "amplification refractory mutation system (ARMS) allele-specific real-time PCR." We determined that the ratio of donor cell to recipient cytoplast mtDNA copy number was 0.9% before nuclear transfer. Therefore, we concluded that the percentage of donor cell mtDNA in the heteroplasmic intersubspecific cloned animals is in accordance with neutral transmission of donor mtDNA. We determined an amino acid sequence divergence of up to 1.3% for the two subspecies-specific mtDNA haplotypes. In addition, intrasubspecific B. indicus heteroplasmy of approximately 1% (but up to 7.3 and 12.7% in muscle and follicular cells of one animal) was detected in 7 out of the 9 B. indicus intrasubspecific cloned cattle.     

BTI基因转染诱导EC9706细胞凋亡及G_1阻滞

为了研究荞麦胰蛋白酶抑制剂(buckwheat trypsin inhibitor,BTI)对肿瘤细胞凋亡与细胞周期的影响,构建增强型绿色荧光蛋白(EGFP)与BTI融合蛋白真核表达质粒.将BTI基因成功克隆至pEGFP-N1中转染食管癌EC9706细胞后,激光共聚焦显微镜镜检显示,BTI-EGFP获得良好表达.表达的融合蛋白大部分分布于细胞核,在细胞质中有少量分布.Western印迹检测可见约27kD和36 kD的特异性条带.流式细胞术分析结果显示,BTI能够诱导EC9706细胞发生凋亡,并使细胞停滞于G0/G1期.     

Improvement of canine somatic cell nuclear transfer procedure

The purpose of the present study on canine somatic cell nuclear transfer (SCNT) was to evaluate the effects of fusion strength, type of activation, culture media and site of transfer on developmental potential of SCNT embryos. We also examined the potential of enucleated bovine oocytes to serve as cytoplast recipients of canine somatic cells. Firstly, we evaluated the morphological characteristics of in vivo-matured canine oocytes collected by retrograde flushing of the oviducts 72 h after ovulation. Secondly, the effectiveness of three electrical strengths (1.8, 2.3 and 3.3 kV/cm), used twice for 20 micros, on fusion of canine cytoplasts with somatic cells were compared. Then, we compared: (1) chemical versus electrical activation (a) after parthenogenetic activation or (b) after reconstruction of canine oocytes with somatic cells; (2) culture of resulting intergeneric (IG) embryos in either (a) mSOF or (b) TCM-199. The exposure time to 6-DMAP was standardized by using bovine oocytes reconstructed with canine somatic cells. Bovine oocytes were used for SCNT after a 22 h in vitro maturation interval. The fusion rate was significantly higher in the 3.3 kV/cm group than in the 1.8 and 2.3 kV/cm treatment groups. After parthenogenesis or SCNT with chemical activation, 3.4 and 5.8%, respectively, of the embryos developed to the morula stage, as compared to none of the embryos produced using electrical activation. Later developmental stages (8-16 cells) were transferred to the uterine horn of eight recipients, but no pregnancy was detected. However, IG cloned embryos (bovine cytoplast/canine somatic cell) were capable of in vitro blastocyst development. In vitro developmental competence of IG cloned embryos was improved after exposure to 6-DMAP for 4 h as compared to 0, 2 or 6h exposure, although the increase was not significantly different among culture media. In summary, for production of canine SCNT embryos, we recommend fusion at 3.3 kV/cm, chemical activation, culture in mSOF medium and transfer of presumptive zygotes to the oviduct of recipient animals. The feasibility of IG production of cloned canine embryos using bovine cytoplasts as recipient of canine somatic cells was demonstrated.     

The effects of delayed activation and MG132 treatment on nuclear remodeling and preimplantation development of embryos cloned by electrofusion are correlated with the age of recipient cytoplasts

The electrofusion method, used extensively in livestock cloning, cannot be used in mice, because it is believed that the mouse oocytes are more susceptible to detrimental effects of electrical stimulus than oocytes from other species. Reports on whether a delayed activation after electrofusion and a premature chromosome condensation (PCC) is essential for efficient cloning are inconclusive. To address these issues, effects of pulsing on activation and MPF activity of nonenucleated oocytes and effects of delayed activation and MG132 treatment on donor nuclear PCC and preimplantation development of embryos cloned by electrofusion or nuclear injection were compared between different cytoplast ages in mice and goats. The results indicated that the use of oocytes collected early after donor stimulation would make it possible to conduct somatic cell nuclear transfer in mice by electrofusion. Whether a delayed activation is essential was dependent upon the age, or rather, the level, of MPF activity of the cytoplasts at the time of electrofusion, as was the requirement for MG132 treatment. The competence for blastocyst formation of cloned embryos was highly correlated with the level of donor nuclear PCC in recipient cytoplasts. The nuclear injection technique was more adaptable to older cytoplast ages, and hence less dependent on drugs for inhibition of MPF inactivation, compared to electrofusion.     

Cell cycle synchronization of porcine fetal fibroblasts by serum deprivation initiates a nonconventional form of apoptosis

The success of somatic nuclear transfer depends upon the cell cycle stage of the donor nucleus and the recipient cytoplast. Recently, we established efficient cell cycle synchronization protocols for porcine fetal fibroblasts and found that serum withdrawal leads to cell death. Here, we examined whether the specific cell death induced by serum deprivation follows the conventional apoptotic pathway in porcine fibroblasts. Terminal deoxynucleotidyl transferase mediated dUTP nick end-labeling analysis revealed that serum deprivation induced DNA fragmentation in a concentration and time dependent manner. Semiquantitative RT-PCR and Western blotting revealed activation of cell death-related genes Bak and Bax of the Bcl-2 family. However, electrophoretic analysis of genomic DNA from serum deprived cells did not provide evidence for the internucleosomal DNA cleavage which is characteristic of conventional apoptosis. Thus, serum deprivation triggers initial steps in the apoptotic pathway, but does not lead to the typical oligonucleosome-sized DNA ladder. These findings contribute to a better understanding of apoptotic pathways and aid to define essential parameters of the donor nucleus for successful somatic cloning.     

Improvement of a porcine somatic cell nuclear transfer technique by optimizing donor cell and recipient oocyte preparations

This study was conducted to improve a porcine somatic cell nuclear transfer (SCNT) technique by optimizing donor cell and recipient oocyte preparations. Adult and fetal fibroblasts, and cumulus and oviduct cells were used as donor cells, and in vivo- and in vitro-matured oocytes were employed as recipient oocytes. The percentages of fusion and development to the blastocyst stage, the ratio of blastocysts to 2-cell embryos, and cell number of blastocysts were monitored as experimental parameters. In Experiment 1, donor cells of four different types were transferred to enucleated oocytes matured in vitro, and more (P < 0.05) blastocysts were derived from SCNT of fetal fibroblasts than from that of other cells (15.9% versus 3.1-7.9%). For SCNT using fetal fibroblasts, increasing the number of subcultures up to 15 times did not improve developmental competence to the blastocyst stage (12.2-16.7%). In Experiment 2, fetal fibroblasts were transferred to enucleated oocytes that matured in vivo or in vitro. When parthenogenetic activation of both types of oocytes was conducted as a preliminary control treatment, a significant increase in blastocyst formation was found for in vivo-matured compared with in vitro-matured oocytes (36.4% versus 29.5%). However, no improvement was achieved in SCNT using in vivo-matured oocytes. In conclusion, the type of donor somatic cell is important for improving development after porcine SCNT, and fetal fibroblasts were the most effective among examined cells. A system with good reproducibility has been established using fetal fibroblasts as the donor karyoplast after subculturing 1-10 times, and using both in vivo and in vitro-matured oocytes as the recipient cytoplast.     

牛体细胞核移植技术研究进展

对近年来牛体细胞核移植技术研究的进展作一综述。其中包括:供体细胞种类、传代次数和所处细胞周期的选择;对供体细胞的特殊处理;卵母细胞的采集;传统去核方法的优化、去透明带核移植技术的建立与发展;胚胎重构、激活和体外培养条件的比较与改进等内容。     

Transfer of murine intracisternal A particle phenotype in chloramphenicol-resistant cytoplasts

Murine intracisternal A particles have a number of properties which are common to known RNA tumor viruses, but horizontal transmission has not been previously demonstrated. The apparent absence of infectivity may be related to the failure of these particles to be released from cisternae of endoplasmic reticulum. Previous biological studies using isolated, purified A particles have been compromised by the fact that the isolation procedure requires small amounts of nonionic detergent.Using some techniques of somatic cell hybridization, we have assessed the capacity for A particle genome transfer from positive to negative cells. Since it has been previously shown that some chloramphenicol-resistant cell lines can transfer this resistance in the cytoplasm, we have used this characteristic as a marker for cytoplasmic fragments. Mouse cells containing A particles were mutagenized, and clones resistant to chloramphenicol were selected; by enucleating these cells and fusing the resultant cytoplasts to each of two recipient mouse cell lines negative for A particles, it is possible to identify clones of cells known to be the product of a fusion event between a cytoplast and a whole cell (cybrids). Under these conditions, intracisternal A particles appear in the cybrid clones as a phenotypic trait that has not been segregated over at least 60–80 cell generations.     

Role of mitochondrial DNA replication during differentiation of reprogrammed stem cells

Mitochondrial DNA (mtDNA) is a 16.6 kb genome that encodes for 13 of the 100+ subunits of the electron transfer chain (ETC), whilst the other subunits are encoded by chromosomal DNA. The ETC is responsible for the generation of the majority of cellular ATP through the process of oxidative phosphorylation (OXPHOS). mtDNA is normally inherited from the population present in the mature oocyte just prior to fertilisation. However, following somatic cell nuclear transfer (SCNT), mtDNA can be transmitted from both the donor cell and the recipient oocyte. This heteroplasmic transmission of mtDNA is a random event and does not appear to be related to the amount of mtDNA contributed by the donor cell. The distribution of mtDNA is randomly segregated between blastomeres and differentiating tissues, and therefore the mtDNA complement transmitted to offspring tissue cannot be predicted. mtDNA divergence between the cytoplast and the donor cell in intra- and inter-specific crosses favours a slightly more diverse mtDNA haplotype. However, this is limited as interspecies SCNT (iSCNT) genetic divergence contributes to developmental failure. SCNT embryos demonstrate a plethora of aberrantly reprogrammed characteristics including the uncoordinated regulation of the mtDNA replication factors. This results in increased mtDNA copy number during preimplantation development and propagates the replication of donor cell mtDNA. These failures are likely to be a consequence of incompatible nuclear- and mtDNA -encoded proteins interacting within the ETC thus reducing ATP production. The outcomes would be similar to the severely debilitating or even fatal mtDNA diseases associated with genetic rearrangements to mtDNA or mtDNA depletion type syndromes and have serious implications for any form of karyoplast transfer approach. The only method to overcome the problems of heteroplasmy in SCNT embryos is to completely deplete the donor cell of its mtDNA prior to SCNT.     

Donor-host mitochondrial compatibility improves efficiency of bovine somatic cell nuclear transfer

Background  

The interaction between the karyoplast and cytoplast plays an important role in the efficiency of somatic cell nuclear transfer (SCNT), but the underlying mechanism remains unclear. It is generally accepted that in nuclear transfer embryos, the reprogramming of gene expression is induced by epigenetic mechanisms and does not involve modifications of DNA sequences. In cattle, oocytes with various mitochondrial DNA (mtDNA) haplotypes usually have different ATP content and can further affect the efficiency of in vitro production of embryos. As mtDNA comes from the recipient oocyte during SCNT and is regulated by genes in the donor nucleus, it is a perfect model to investigate the interaction between donor nuclei and host oocytes in SCNT.     

继代核移植能成倍提高来自奶山羊卵胞质体的异种间核移植重构胚的发育率

为了提高异种间核移植重构胚的发育率,本研究以体内排放的奶山羊成熟卵为供胞质的受体细胞,以人、兔、波尔山羊等的异种或亚种体细胞的原代核移植（Primary Somatic Cell Nuclear Transfer,PSCNT）重构早胚（8-16细胞期）的卵裂球作供核体,观察经亚种或异种卵胞质体短期“修饰”的核再移植产生的继代（Secondary SCNT,SSCNT）重构胚的着床前发育潜能。结果：人、兔、波尔山羊的继代桑椹／囊胚发育率均显著地高于其PSCNT胚胎（人,14．81％VS．7．79％;兔,23．53％VS．12．50％;波尔羊,55．35％VS．24．53％）;这些早胚的各阶段发育时程仍遵循供核体动物正常受精卵的发育时程。结果启示：奶山羊成熟卵胞质对异种体细胞核亦具一定的去分化能力,能支持重构胚发育到囊胚;异种重构胚的发育特征是由供体核所决定的;继代核移植几乎能够成倍提高异种间重构胚的着床前发育率,提示核的去分化完全是在母型信息主导的调控之下完成的,而进一步发育的时序似乎是由核决定的：成倍延长在含母型信息主导调控环境中的时间能成倍提高SCNT重构胚的着床前发育率。     

The possible role of cell cycle stage in mammalian cloning

Progress in mammalian cloning started from cloning embryos (of mice, rats, rabbits, sheep, goats, pigs, cattle and rhesus monkeys) and culminated in obtaining clones of sheep, cattle, pigs and mice from adult somatic cells. Knowing the relationship between the cell cycles of the recipient and the donor of cell nucleus in embryonic cloning by nuclear transfer one can adjust the phases of the cell cycle properly. Metaphase II recipients accept G1 (in most species) or G2 donors (in the mouse). Interphase recipients can harbour nuclei in all stages of cell cycle. Relatively little is known about somatic cloning. Two attitudes are applied: either the donor is in the G0 phase or the recipient is in a prolonged MII phase.     

Sertoli cells dictate spermatogonial stem cell niches in the mouse testis

Sustained spermatogenesis in adult males relies on the activity of spermatogonial stem cells (SSCs). In general, tissue-specific stem cell populations such as SSCs are influenced by contributions of support cells that form niche microenvironments. Previous studies have provided indirect evidence that several somatic cell populations and the interstitial vasculature influence SSC functions, but an individual orchestrator of niches has not been described. In this study, functional transplantation of SSCs, in combination with experimental alteration of Sertoli cell content by polythiouracil (PTU)-induced transient hypothyroidism, was used to explore the relationship of Sertoli cells with SSCs in testes of adult mice. Transplantation of SSCs from PTU-treated donor mice into seminiferous tubules of normal recipient mice revealed a greater than 3-fold increase in SSCs compared to those from testes of non-PTU-treated donors. In addition, use of PTU-treated mice as recipients for transplantation of SSCs from normal donors revealed a greater than 3-fold increase of accessible niches compared to those of testes of non-PTU treated recipient mice with normal numbers of Sertoli cells. Importantly, the area of seminiferous tubules bordered by interstitial tissue and percentage of seminiferous tubules associated with blood vessels was found to be no different in testes of PTU-treated mice compared to controls, indicating that neither the vasculature nor interstitial support cell populations influenced the alteration of niche number. Collectively, these results provide direct evidence that Sertoli cells are the key somatic cell population dictating the number of SSCs and niches in mammalian testes.