Effect of timing of the removal of oocyte chromosomes before or after injection of somatic nucleus on development of NT embryos

Cloning methods are now well described and becoming routine. Yet the frequency at which live cloned offspring are produced (as a percentage of starting one-cell embryos) remains below 5% irrespective of nucleus donor species or cell type. In considering the cause(s) of this universally low efficiency, features common to all cloning protocols are strong candidates. One such shared feature is enucleation; the donor nucleus is inserted into an enucleated cytoplast (ooplast). However, it is not known whether a nucleus-free metaphase II oocyte is developmentally impaired other than by virtue of lacking chromosomes, or if in nuclear transfer protocols, enucleation removes factors necessary to reprogram the incoming nucleus. We have here investigated the role of enucleation in nuclear transfer. Three hours after the injection of cumulus cell nuclei into non-enucleated oocytes, 65% contained two distinct metaphase spindles, with the remainder exhibiting a single spindle in which oocyte-derived and nucleus donor chromosomes were mixed. However, staining only one hour after donor nucleus insertion revealed that most had two discrete spindles. In the absence of staining, the donor nucleus spindle was not visible. This provided a straightforward way to identify and select the oocyte-derived metaphase chromosomes 1 h after donor nucleus microinjection, and 34-41% cloned embryo developed to the morulla-blastocyst stage following Sr(2+)-induced activation. Of these, two (1% of starting one-cell embryos) developed to term, an efficiency which is comparable to that obtained for controls (6 clone; 1-2%) in which enucleation preceded nuclear transfer. In conclusion, the timing of the removal of oocyte chromosomes before or after injection of somatic nucleus had no effect on cloned embryo development. These findings argue that neither oocyte chromosome depletion per se, nor the potential removal of "reprogramming" factors during enucleation explain the low efficiency of nuclear transfer cloning.     

核移植后的细胞核再程序化机制研究进展

目前动物克隆技术体系极待完善,其极低的成功率及克隆动物普遍存在的早衰、早天现象是阻碍研究深入进行的首要问题,其突破的关键在于对核移植后的细胞核再程序化机制的阐明。从移植核在结构上的重塑、移植核与受体卵细胞质所处的细胞周期及其相互作用、重构胚与两性胚在分子水平的变化等多方面研究表明：受体细胞质的环境对于细胞核的再程序化至关重要,处于有丝分裂各时期的细胞作为核供体一旦移植到卵母细胞后,移植核在卵质环境里将出现结构上的重塑和分子的再程序化;移植核与受体卵问细胞周期的相容性、重构胚的染色体倍性的正确与否,可能是决定重构胚发育率高低的重要因素;合子型基因激活是基因表达再程序化的关键事件之一;印记基因对于体细胞克隆动物移植核的再程序化过程可能起着非常独特的作用。     

Somatic cell nuclear transfer efficiency: How can it be improved through nuclear remodeling and reprogramming?

Fertile offspring from somatic cell nuclear transfer (SCNT) is the goal of most cloning laboratories. For this process to be successful, a number of events must occur correctly. First the donor nucleus must be in a state that is amenable to remodeling and subsequent genomic reprogramming. The nucleus must be introduced into an oocyte cytoplasm that is capable of facilitating the nuclear remodeling. The oocyte must then be adequately stimulated to initiate development. Finally the resulting embryo must be cultured in an environment that is compatible with the development of that particular embryo. Much has been learned about the incredible changes that occur to a nucleus after it is placed in the cytoplasm of an oocyte. While we think that we are gaining an understanding of the reorganization that occurs to proteins in the donor nucleus, the process of cloning is still very inefficient. Below we will introduce the procedures for SCNT, discuss nuclear remodeling and reprogramming, and review techniques that may improve reprogramming. Finally we will briefly touch on other aspects of SCNT that may improve the development of cloned embryos.     

Cloned endangered species takin (Budorcas taxicolor) by inter-species nuclear transfer and comparison of the blastocyst development with yak (Bos grunniens) and bovine

Interspecies cloning might be used as an effective method to conserve endangered species and to support the study of nuclear-cytoplasm interaction. In this study, we describe the development of takin-bovine embryos in vitro produced by fusing takin ear fibroblasts with enucleated bovine oocytes and examine the fate of mitochondrial DNA in these embryos. We also compare the blastocyst development of takin-bovine embryos with yak-bovine and bovine-bovine embryos and compare the cell numbers of the blastocyst. Our results indicate that: (1) takin-bovine cloned embryos can develop to the blastocyst stage in vitro (5%), (2) blastocyst mitochondria DNA are derived primarily from bovine oocytes in spite of a little takin donor cell mitochondrial DNA, (3) using the same cloned protocol, development efficiency is significantly different between bovine-bovine cloning, yak-bovine, and takin-bovine cloning (48 vs. 28% vs. 5%, P < 0.01), and (4) cell numbers in the blastocysts of the three species of embryos were not different. These results suggest that the bovine oocytes can reprogram the takin, yak, and bovine fibroblast nuclei. However, the development efficiency of intra-species cloning tends to be higher than inter-species cloning; the more close the species of the donor cell is to the recipient oocyte (yak versus takin), the greater the blastocyst development in vitro.     

Blastocysts produced by nuclear transfer between chicken blastodermal cells and rabbit oocytes

Interspecies nuclear transfer (INT) has been used as an invaluable tool for studying nucleus-cytoplasm interactions; and it may also be a method for rescuing endangered species whose oocytes are difficult to obtain. In the present study, we investigated interaction of the chicken genome with the rabbit oocyte cytoplasm. When chicken blastodermal cells were transferred into the perivitelline space of rabbit oocytes, 79.3% of the couplets were fused and 9.7% of the fused embryos developed to the blastocyst stage. Both M199 and SOF medium were used for culturing chicken-rabbit cloned embryos; embryo development was arrested at the 8-cell stage obtained in SOF medium, while the rates of morulae and blastocysts were 12.1 and 9.7%, respectively, in M199 medium. Polymerase chain reaction (PCR) amplification of nuclear DNA and karyotype analyses confirmed that genetic material of morulae and blastocysts was derived from the chicken donor cells. Analysis mitochondrial constitution of the chicken-rabbit cloned embryos found that mitochondria, from both donor cells and enucleated oocytes, co-existed. Our results suggest that: (1) chicken genome can coordinate with rabbit oocyte cytoplasm in early embryo development; (2) there may be an 8- to 16-cell stage block for the chicken-rabbit cloned embryos when cultured in vitro; (3) mitochondrial DNA from the chicken donor cells was not eliminated until the blastocyst stage in the chicken-rabbit cloned embryos; (4) factors existing in ooplasm for somatic nucleus reprogramming may be highly conservative.     

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。     

The fate of mitochondria in Ibex-hirus reconstructed early embryos

Inter-species nuclear transfer could be used to preserve North Goat (Capra ibex), an endangered species. We established the culture conditions for ibex-hirus reconstructed embryos and optimized the method for DNA extractions of a single cell and early cloned embryo. By using mitochondria-specific probes of ibex and hirus respectively we found that mitochondria of donor cells can co-exist with recipients in 1-cell and 2-cell stages of the reconstructed embryos but not in the following developmental stages.     

Genetic and epigenetic aspects of cloning and potential effects on offspring of cloned mammals

Although the biological mechanisms by which host cytoplasm and donor nuclei interact to produce a developmentally competent reconstructed embryo remain largely unknown, some advances have been made to our understanding of the genetic and epigenetic factors involved in the of reprogramming of the donor nucleus. Genetic alterations, which comprise changes to the genetic information in both the nuclear and cytoplasm compartments, are passed on to subsequent generations at fertilization and are a potential source of variation among cloned animals and their offspring. Apart from the major chromosomal anomalies found in developmentally arrested embryos and fetuses, less detrimental rearrangements and/or mutations are likely to go unnoticed in most donor cell karyotypes, suggesting that such problems could lead to inheritable anomalies among clones and their offspring. Mitochondrial DNA is also relevant to cloning because most animals inherit most or all of their mitochondria from the host oocyte. Epigenetic alterations to the DNA or to the histone packaging proteins are independent of gene sequences. Aberrant epigenetic events may lead to variable gene expression or mitosis and consequent effects on development and phenotype. Although much of the epigenetic marking is reset during embryogenesis and development, the impact of epimutations on progeny remains unexplored.     

The Fate of Mitochondria in Ibex-hirus Reconstructed Early Embryos

Nuclear transfer can be used to maintain limited popu-lations of highly endangered species [1–3] . Especiallywhen the oocytes of these species are difficult to obtain,inter-species nuclear transfer seems more appropriate forthis goal. The main methods are as follows: somatic cellis injected directly or fused by electroporation with re-cipient enucleated oocyte. Therefore, nDNA as well asmtDNA ought to be transferred totally or partially to theoocyte. Mitochondria provides adenosine triphos…     

核移植与供体细胞

“多莉”羊的诞生是生物界的一个里程碑,它之所以引起如此大的轰动主要是因为它来源于培养的成年绵羊乳腺上皮细胞,这是人类第一次证明分化的体细胞可以被重编程后恢复全能性并最终分化发育成一个动物个体。这说明哺乳动物分化的体细胞核仍具有全套的遗传物质并能够被卵母细胞逆转恢复全能性。然而,关于多莉的供体细胞来源却一直是克隆领域的一个谜。由于体细胞克隆的效率非常低,而用于核移植的供体细胞悬液中往往含有多种类型的细胞,这使得我们很难确切地知道最终获得的克隆动物是来源于哪一种细胞。这种不确定性给我们研究核移植诱导体细胞重编程的机制带来了很大的困难,因此,对供体细胞的研究也是核移植研究领域的一个重要课题,这包括各种组织来源的体细胞是否均可以用于核移植,终末分化的体细胞是否能够用于核移植,组织干细胞是否更有利于体细胞重编程,供体细胞的分化状态是否与核移植的效率有关,死亡的体细胞是否也可以用于核移植等等。本文综述了核移植中与供体细胞相关的最新研究进展。     

MIRO1 influences the morphology and intracellular distribution of mitochondria during embryonic cell division in Arabidopsis

Regulating the morphology and intracellular distribution of mitochondria is essential for embryo development in animals. However, the importance of such regulation is not clearly defined in plants. The evolutionarily conserved Miro proteins are known to be involved in the regulation of mitochondrial morphology and motility. We previously demonstrated that MIRO1, an Arabidopsis thaliana orthologue of the Miro protein, is required for embryogenesis. An insertional mutation in the MIRO1 gene causes arrest of embryonic cell division, leading to abortion of the embryo at an early stage. Here we investigated the role of MIRO1 in the regulation of mitochondrial behaviour in egg cells and early-stage embryos using GFP-labeled mitochondria. Two-photon laser scanning microscopy revealed that, in miro1 mutant egg cells, mitochondria are abnormally enlarged, although egg cell formation is nearly unaffected. After fertilization and subsequent zygotic cell division, the homozygous miro1 mutant two-celled embryo contained a significantly reduced number of mitochondria in its apical cell compared with the wild type, suggesting that the miro1 mutation inhibits proper intracellular distribution of mitochondria, leading to an arrest of embryonic cell division. Our findings suggest that proper mitochondrial morphology and intracellular distribution are maintained by MIRO1 and are vital for embryonic cell division.     

Role of glucose in cloned mouse embryo development

Cloned mouse embryos display a marked preference for glucose-containing culture medium, with enhanced development to the blastocyst stage in glucose-containing medium attributable mainly to an early beneficial effect during the first cell cycle. This early beneficial effect of glucose is not displayed by parthenogenetic, fertilized, or tetraploid nuclear transfer control embryos, indicating that it is specific to diploid clones. Precocious localization of the glucose transporter SLC2A1 to the cell surface, as well as increased expression of glucose transporters and increased uptake of glucose at the one- and two-cell stages, is also seen in cloned embryos. To examine the role of glucose in early cloned embryo development, we examined glucose metabolism and associated metabolites, as well as mitochondrial ultrastructure, distribution, and number. Clones prepared with cumulus cell nuclei displayed significantly enhanced glucose metabolism at the two-cell stage relative to parthenogenetic controls. Despite the increase in metabolism, ATP content was reduced in clones relative to parthenotes and fertilized controls. Clones at both stages displayed elevated concentrations of glycogen compared with parthenogenetic controls. There was no difference in the number of mitochondria, but clone mitochondria displayed ultrastructural alterations. Interestingly, glucose availability positively affected mitochondrial structure and localization. We conclude that cloned embryos may be severely compromised in terms of ATP-dependent processes during the first two cell cycles and that glucose may exert its early beneficial effects via positive effects on the mitochondria.     

The kinetics of donor cell mtDNA in embryonic and somatic donor cell-derived bovine embryos

The mechanisms controlling the outcome of donor cell-derived mitochondrial DNA (mtDNA) in cloned animals remain largely unknown. This research was designed to investigate the kinetics of somatic and embryonic mtDNA in reconstructed bovine embryos during preimplantation development, as well as in cloned animals. The experiment involved two different procedures of embryo reconstruction and their evaluation at five distinct phases of embryo development to measure the proportion of donor cell mtDNA (Bos indicus), as well as the segregation of this mtDNA during cleavage. The ratio of donor cell (B. indicus) to host oocyte (B. taurus) mtDNA (heteroplasmy) from blastomere(NT-B) and fibroblast(NT-F) reconstructed embryos was estimated using an allele-specific PCR with fluorochrome-stained specific primers in each sampled blastomere, in whole blastocysts, and in the tissues of a fibroblast-derived newborn clone. NT-B zygotes and blastocysts show similar levels of heteroplasmy (11.0% and 14.0%, respectively), despite a significant decrease at the 9-16 cell stage (5.8%; p<0.05). Heteroplasmy levels in NT-F reconstructed zygotes, however, increased from an initial low level (4.7%), to 12.9% (p<0.05) at the 9-16 cell stage. The NT-F blastocysts contained low levels of heteroplasmy (2.2%) and no somatic-derived mtDNA was detected in the gametes or the tissues of the newborn calf cloned. These results suggest that, in contrast to the mtDNA of blastomeres, that of somatic cells either undergoes replication or escapes degradation during cleavage, although it is degraded later after the blastocyst stage or lost during somatic development, as revealed by the lack of donor cell mtDNA at birth.     

Nuclear cloning,stem cells,and genomic reprogramming

The generation of adult animals by nuclear cloning from adult donor cells is extremely inefficient, with most clones dying soon after implantation. In contrast, cloning from embryonic stem cell donor nuclei is significanty more efficient than from adult donor cells. However, regardless of donor cell type, all clones that survive to birth and beyond suffer serious phenotypic and gene expression abnormalities. All available evidence is consistent with the notion that the anomalous phenotypes of cloned animals are caused by faulty epigenetic reprogramming of the donor nucleus. Faulty reprogramming appears to be caused by the cloning process itself as well as by the epigenetic state of the donor nucleus. In contrast to reproductive cloning, faulty reprogramming of the donor nucleus does not tend to interfere with the application of nuclear transfer technology for therapeutic purposes (therapeutic cloning).     

Production of calves from G1 fibroblasts.

Since the landmark study of Wilmut et al. describing the birth of a cloned lamb derived from a somatic cell nucleus, there has been debate about the donor nucleus cell cycle stage required for somatic cell nuclear transfer (NT). Wilmut et al. suggested that induction of quiescence by serum starvation was critical in allowing donor somatic cells to support development of cloned embryos. In a subsequent report, Cibelli et al. proposed that G0 was unnecessary and that calves could be produced from actively dividing fibroblasts. Neither study conclusively documented the importance of donor cell cycle stage for development to term. Other laboratories have had success with NT in several species, and most have used a serum starvation treatment. Here we evaluate methods for producing G0 and G1 cell populations and compare development following NT. High confluence was more effective than serum starvation for arresting cells in G0. Pure G1 cell populations could be obtained using a "shake-off" procedure. No differences in in vitro development were observed between cells derived from the high-confluence treatment and from the "shake-off" treatment. However, when embryos from each treatment were transferred to 50 recipients, five calves were obtained from embryos derived from "shake-off" cells, whereas no embryos from confluent cells survived beyond 180 days of gestation. These results indicate that donor cell cycle stage is important for NT, particularly during late fetal development, and that actively dividing G1 cells support higher development rates than cells in G0.     

人-兔异种核移植构建克隆胚的实验研究

“治疗性克隆”是人类最关注的课题之一,而人体细胞核移植是治疗性克隆的基础和前提。异种核移植的方法虽已被引入人体细胞克隆胚的构建,但供体细胞的类型、培养代数及准备方法与其效率之间的关系尚有待探讨。本实验以不同培养代数和不同准备方法的人卵丘细胞、皮肤成纤维细胞和软骨细胞为供体构建了克隆胚,对其发育情况的比较表明,以卵丘细胞为供体时重构胚的体外发育率高于其余二者,差异显著（P〈0．05）;不同培养代数的成纤维细胞克隆胚和不同冷藏天数供体细胞克隆胚体外发育率无明显差异。此外,本实验还尝试用荧光原位杂交法检测所构建的异种克隆胚核遗传物质的来源,结果显示来自人体细胞。本研究表明,人一兔异种核移植构建克隆胚切实可行;体细胞的类型与核移植效率相关;供体细胞的体外培养传代对克隆胚的发育并无影响;而冷藏是一种简便有效的供体细胞准备方法;此外,用FISH方法对重构胚进行核遗传物质的鉴定切实可行。     

Experimental cloning of embryos through human-rabbit inter-species nuclear transfer

Therapeutic cloning,which is based on human somatic cell nuclear transfer,is one of our major research objectives.Though inter-species nuclear transfer has been introduced to construct human somatic cell cloned embryos,the effects of type,passage,and preparation method of donor cells on embryo development remain unclear.In our experiment,cloned embryos were reconstructed with different passage and preparation methods of ossocartilaginous cell,skin fibroblast,and cumulus cells.The cumulus cell embryos showed significantly higher development rates than the other two (P＜0.05).The development rate of embryos reconstructed with skin fibroblasts of different passage number and somatic cells of different chilling durations showed no significant difference.Also,fluorescence in situ hybridization (FISH)was conducted to detect nuclear derivation of the embryos.The result showed that the nuclei of the inter-species cloned embryo cells came from human.We conclude that (1)cloned embryos can be constructed through human-rabbit interspecies nuclear transfer;(2)different kinds of somatic cells result in different efficiency of nuclear transfer,while in vitro passage of the donor does not influence embryo development;(3)refrigeration is a convenient and efficient donor cell preparation method.Finally,it is feasible to detect DNA gcnotype through FISH.