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。     

Cloned calves from chromatin remodeled in vitro

We have developed a novel system for remodeling mammalian somatic nuclei in vitro prior to cloning by nuclear transplantation. The system involves permeabilization of the donor cell and chromatin condensation in a mitotic cell extract to promote removal of nuclear factors solubilized during chromosome condensation. The condensed chromosomes are transferred into enucleated oocytes prior to activation. Unlike nuclei of nuclear transplant embryos, nuclei of chromatin transplant embryos exhibit a pattern of markers closely resembling that of normal embryos. Healthy calves were produced by chromatin transfer. Compared with nuclear transfer, chromatin transfer shows a trend toward greater survival of cloned calves up to at least 1 mo after birth. This is the first successful demonstration of a method for directly manipulating the somatic donor chromatin prior to transplantation. This procedure should be useful for investigating mechanisms of nuclear reprogramming and for making improvements in the efficiency of mammalian cloning.     

Reprogramming is essential in nuclear transfer

Fertile offspring have been produced by nuclear transfer from adult somatic cells in several mammalian species (Wilmut et al., 1997; Kato et al., 1998; Wakayama et al., 1998; Polejaeva et al., 2000; Chesne et al., 2002; Shin et al., 2002; Zhou et al., 2003). Various possible causes have been suggested for the overall low efficiency (Perry and Wakayama, 2002). Notably, however, it has not yet been clearly demonstrated whether reprogramming after nuclear transfer is necessary for successful cloning. Here we show that reprogramming is essential in nuclear transfer, by comparing the developmental efficiency after the transfer of cumulus cell nuclei with that for zygote nuclei. Nuclear transfers from blastomeres of a series of pre-implantation stages showed further that, as development proceeds, the nuclei progressively lose their potency and become more difficult to reprogram upon their transfer into enucleated MII oocytes. We also found that naturally ovulated oocytes are much better recipients of a nucleus than are superovulated oocytes, which have been used in all the nuclear transfer experiments reported so far. This indicates that cloning efficiency can also be increased to some extent by technical improvements. All these results enable us to distinguish more clearly between the inherent problem of reprogramming and technical problems associated with materials, manipulation, and in vitro culture.     

供体细胞的不同选择和处理对重编程过程的影响

摘要: 供体细胞核移入去核的卵母细胞后, 必定要经过表观遗传修饰的重编程过程, 回到胚胎开始发育的全能状态。若重编程过程不完全, 必定会导致克隆效率降低。但是, 体细胞核的重编程能力不仅仅是在其移入去核的卵母细胞后所体现, 它在不同的供体细胞当中的潜能也是不尽相同的。并且, 对供体细胞进行不同的处理, 也会导致其重编程的能力和程度不同。文章首先阐述了供体细胞的类型、代数、周期、年龄以及物种的不同选择对其核移植后重编程过程的不同影响, 其后又通过对供体细胞的冷冻保存, 血清饥饿以及不同试剂的处理等方面对重编程过程所起到的作用作出了概况性的论述与分析     

Reprogramming of bovine somatic cell nuclei is not directly regulated by maturation promoting factor or mitogen-activated protein kinase activity

Cloned mammals with normal fertility have been produced by nuclear transfer. Thus, oocyte cytoplasm has the ability to convert differentiated somatic cell nuclei into a state that resembles the conditions that occur at fertilization (nuclear reprogramming). Despite the long-held assumption that reprogramming factors are present in mammalian oocytes, the molecular nature of these factors is not known. The present study demonstrates that the process of nuclear reprogramming is not directly regulated by maturation promoting factor or mitogen-activated protein kinase activity. The potential for nuclear-transferred oocytes to develop to the blastocyst stage was not different when somatic cells at the M phase were fused with oocytes activated with ionomycin and cycloheximide 1-5 h before (12%-22%) but was significantly decreased when oocytes were activated 6 h before (1%). Further molecular studies on the differences between oocytes with and without reprogramming potential are required and will be useful for the identification of reprogramming factors.     

Nuclear reprogramming in nuclear transplant rabbit embryos

The first six genetically verified nuclear transplant rabbits have been produced in this study. Individual eight-cell stage embryo blastomeres were transferred and fused with enucleated mature oocytes of which six full-term offspring were produced out of 164 manipulated eggs. The following efficiency rates were determined for the nuclear transplantation procedure: chromosomal removal from oocytes, 92%; fusion rate, 84%; activation rate, 46%; embryo transfer rate, 27%. Additional reasons for the low efficiency rate of nuclear transplant embryos may include limited development due to aging in recipient oocytes and asynchronous transfers of manipulated embryos to recipient females. The successful development to term may have been due to the ability of the mature oocyte to reprogram the eight-cell stage nuclei. The number of cells in blastocysts derived from isolated eight-cell blastomeres (18 +/- .08) was lower than that of nonmanipulated pronuclear (106 +/- 5.1) and nuclear transplant embryos derived from eight-cell stage nuclei (91 +/- 10.2) (p less than 0.001). This evidence along with the significant amount of nuclear swelling in nuclear transplant embryos and a delay in the time of blastocyst formation indicate that nuclear reprogramming had taken place in these embryos. Successful nuclear reprogramming indicates that serial transfers could result in the expanded multiplication of mammalian embryos.     

In vitro development of yak (Bos grunniens) embryos generated by interspecies nuclear transfer

Interspecies cloning may be used as an effective method to conserve highly endangered species, but at present it suffers from relatively low levels of efficiency. In order to find a technique that could be used in conservation of the wild yak (Bos grunniens), we designed in six separate experiments to investigate the following factors that might influence the efficiency of interspecies cloning: (1) maturation rates of the recipient bovine oocytes; (2) nuclear donor cell types; (3) age of the yak from which the yak ear skin fibroblast cell line originated; (4) donor cells treated with or without serum starvation; (5) nuclear donor gained from fresh cells or frozen-thawed cells; (6) effect of 0.5 or 1.5 h from fusion to activation. The results of experiment 1 showed that when recipient oocytes in a replicate had a maturation rate of <40% (34+/-3.0%; three replicates) the proportion of nuclear transferred oocytes that developed to blastocyst was 2+/-1.1%, which was significantly lower (P<0.01) than the 25+/-3.2% achieved when the recipient oocyte maturation rate was 71+/-3.7% (three replicates). The efficiency of blastocyst production was increased substantially (P<0.05) when the time from fusion to activation increased from 0.5 h (21+/-2.3%; three replicates) to 1.5 h (35+/-3.5%; five replicates; experiment 6). There was no significant effect of the source of the donor nuclei (ear skin fibroblast or cumulus cells), the age of the animal (3 months or 4 years) from which the donor cells were derived, serum deprivation of the donor cells, or the use of fresh or frozen-thawed donor cells (experiments 2-5). Transfer of three interspecies cloned blastocysts to each of 108 bovine recipients resulted in two pregnancies being established that did not survive to day 120 of gestation.     

Novel approaches and hurdles to somatic cloning in cattle

The overall efficiency of somatic cloning in cattle is still low. Many factors are necessary for successful birth of live offspring. Among them, the source of donor cells reveals the importance of the donor genotype but also the influence of the cell line itself. The cell cycle stage has been intensively investigated, and recent results indicate that, in cattle, the G0 stage of the donor nuclei is not a prerequisite for reprogramming, as highly proliferating cultured fibroblasts also result in live offspring after nuclear transfer. A technical approach using direct microinjection of fibroblast nuclei, instead of fusion of the whole cell, has proved to result in high in vitro development rates in cattle. However, full-term development of somatic cloned embryos is still limited by long-lasting effects and a high incidence of losses at periimplantation time (as well as in late gestation and around calving).     

Mouse cloning with nucleus donor cells of different age and type

We have tested different cell types as sources for nucleus donors to determine differences in cloning efficiency. When donor nuclei were isolated from cumulus cells and injected into recipient oocytes from adult hybrid mice (B6D2F1 and B6C3F1), the success rate of cloning was 1.5-1.9%. When cumulus cell donor nuclei were isolated from adult inbred mice (C57BL/6, C3H/He, DBA/2, 129/SvJ, and 129/SvEvTac), reconstructed oocytes did not develop to full term or resulted in a very low success rate (0-0.3%) with the exception of 129 strains which yielded 0.7-1.4% live young. When fetal (13.5-15.5 dpc), ovarian, and testicular cells were used as nucleus donors, 2.2 and 1.0% of reconstructed oocytes developed into live offspring, respectively. When various types of adult somatic cells (fibroblasts, thymocytes, spleen cells, and macrophages) were used, oocytes receiving thymocyte nuclei never developed beyond implantation, whereas those receiving the nuclei of other cell types did. These results indicate that adult somatic cells are not necessarily inferior to younger cells (fetal and ES cells) in the context of mouse cloning. Although fetal cells are believed to have less genetic damage than adult somatic cells, the success rate of cloning using any cell types were very low. This may largely be due to technical problems and/or problems of genomic reprogramming by oocytes rather than the accumulation of mutational damage in adult somatic cells.     

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.     

The cytoplasm of mouse germinal vesicle stage oocytes can enhance somatic cell nuclear reprogramming

In mammalian cloning, evidence suggests that genomic reprogramming factors are located in the nucleus rather than the cytoplasm of oocytes or zygotes. However, little is known about the mechanisms of reprogramming, and new methods using nuclear factors have not succeeded in producing cloned mice from differentiated somatic cell nuclei. We aimed to determine whether there are functional reprogramming factors present in the cytoplasm of germinal vesicle stage (GV) oocytes. We found that the GV oocyte cytoplasm could remodel somatic cell nuclei, completely demethylate histone H3 at lysine 9 and partially deacetylate histone H3 at lysines 9 and 14. Moreover, cytoplasmic lysates of GV oocytes promoted somatic cell reprogramming and cloned embryo development, when assessed by measuring histone H3-K9 hypomethylation, Oct4 and Cdx2 expression in blastocysts, and the production of cloned offspring. Thus, genomic reprogramming factors are present in the cytoplasm of the GV oocyte and could facilitate cloning technology. This finding is also useful for research on the mechanisms involved in histone deacetylation and demethylation, even though histone methylation is thought to be epigenetically stable.     

Factors controlling the loss of immunoreactive somatic histone H1 from blastomere nuclei in oocyte cytoplasm: a potential marker of nuclear reprogramming

Nuclei of differentiated cells can acquire totipotency following transfer into the cytoplasm of oocytes. While the molecular basis of this nuclear reprogramming remains unknown, the developmental potential of nuclear-transfer embryos is influenced by the cell-cycle stage of both donor and recipient. As somatic H1 becomes immunologically undetectable on bovine embryonic nuclei following transfer into ooplasm and reappears during development of the reconstructed embryo, suggesting that it may act as a marker of nuclear reprogramming, we investigated the link between cell-cycle state and depletion of immunoreactive H1 following nuclear transplantation. Blastomere nuclei at M-, G1-, or G2-phase were introduced into ooplasts at metaphase II, telophase II, or interphase, and the reconstructed embryos were processed for immunofluorescent detection of somatic histone H1. Immunoreactivity was lost more quickly from donor nuclei at metaphase than at G1 or G2. Regardless of the stage of the donor nucleus, immunoreactivity was lost most rapidly when the recipient cytoplast was at metaphase and most slowly when the recipient was at interphase. When the recipient oocyte was not enucleated, however, immunoreactive H1 remained in the donor nucleus. The phosphorylation inhibitors 6-DMAP, roscovitine, and H89 inhibited the depletion of immunoreactive H1 from G2, but not G1, donor nuclei. In addition, immunoreactive H1 was depleted from mouse blastomere nuclei following transfer into bovine oocytes. Finally, expression of the developmentally regulated gene, eIF-1A, but not of Gapdh, was extinguished in metaphase recipients but not in interphase recipients. These results indicate that evolutionarily conserved cell-cycle-regulated activities, nuclear elements, and phosphorylation-linked events participate in the depletion of immunoreactive histone H1 from blastomere nuclei transferred in oocyte cytoplasm and that this is linked to changes in gene expression in the transferred nucleus.     

Nuclear remodelling and the developmental potential of nuclear transferred porcine oocytes under delayed-activated conditions

It is still unclear whether nuclear envelope breakdown and premature chromosome condensation are essential for the reprogramming of the donor nucleus following somatic nuclear transfer. To address this, we determined the ability of delayed-activated or simultaneously activated porcine oocytes to undergo nuclear remodelling and development following somatic cell nuclear transfer. A small microtubule aster was observed in association with decondensed chromatin following nuclear transfer, suggesting the introduction of a somatic cell centrosome. In the delayed-activated condition, most fibroblast nuclei divided into two chromosome masses and two pronuclear-like structures following transfer into oocytes. In contrast, fibroblast nuclei in the simultaneously activated condition formed a large, swollen, pronuclear-like structure. Microtubule asters were organised in the vicinity of the nucleus regardless of the number of nuclei. More reconstructed oocytes developed to the blastocyst stage in the delayed-activated condition than in the simultaneously activated condition (p < 0.05). Nine piglets were born from two recipient sows following transfer of delayed-activated reconstructed oocytes, while none developed to full term in the simultaneously activated condition. Fingerprint analysis showed that the PCR-RFLP patterns of the nine offspring were identical to that of the donor pig. These results suggest that the activation of recipient oocytes during nuclear transfer probably relates to the nuclear remodelling process, which can affect the ability of embryos created by somatic cell nuclear transfer to develop.     

哺乳动物核移植中供核与受体卵胞质细胞周期的相互关系

就供核与受体卵胞质细胞周期的相互关系问题进行了综述.核移植技术不管是在基础理论,还是在应用研究中都具有广泛的应用价值,但核移植的效率却很低,其根本原因是与核移植相关的许多基础理论问题尚不清楚,对这些问题的研究发现,维持重构卵核的正确倍性,并使其重新程序化是核移植成功的关键,不同的胞质受体及不同的供体细胞及其状态均对重构胚的发育有影响.     

Dynamics of lamin A/C in porcine embryos produced by nuclear transfer

This study was conducted to investigate the presence of lamin A/C in porcine nuclear transfer embryos and to determine whether lamin A/C can serve as a potential marker for nuclear reprogramming. First, lamin A/C was studied in oocytes and embryos produced by fertilization or parthenogenetic oocyte activation. We found that lamin A/C was present in the nuclear lamina of oocytes at the germinal vesicle stage while it was absent in mature oocytes. Lamin A/C was detected throughout preimplantation development in both in vivo-derived and parthenogenetic embryos. Incubation of the activated oocytes in the presence of alpha-amanitin (an inhibitor of RNA polymerase II), or cycloheximide (a protein synthesis inhibitor) did not perturb lamin A/C assembly, indicating that the assembly resulted from solubilized lamins dispersed in the cytoplasm. In nuclear transfer embryos, the lamin A/C signal that had previously been identified in fibroblast nuclei disappeared soon after fusion. It became detectable again after the formation of the pronucleus-like structure, and all nuclear transfer embryos displayed lamin A/C staining during early development. Olfactory bulb progenitor cells lacked lamin A/C; however, when such cells were fused with enucleated oocytes, the newly formed nuclear envelopes stained positive for lamin A/C. These findings suggest that recipient oocytes remodel the donor nuclei using type A lamins dispersed in the ooplasm. The results also indicate that lamin A/C is present in the nuclear envelope of pig oocytes and early embryos and unlike in some other species, its presence after nuclear transfer is not an indicator of erroneous reprogramming.     

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.     

Nuclear transplantation in the pig embryo: nuclear swelling

The transfer of nuclei from cleavage stage embryos to enucleated activated meiotic metaphase II oocytes results in a reprogramming of the transferred nucleus such that it behaves as a zygotic nucleus. One estimator of nuclear reprogramming is nuclear swelling after nuclear transfer. The diameter of nuclei after nuclear transfer was not found to be dependent upon the amount of cytoplasm transferred with the donor cell or the amount of cytoplasm in the recipient cell. Nuclei from 4-, 8-, and 16-cell stage embryos swelled to a similar diameter after nuclear transfer (26.9, 27.3, and 27.2 microns, respectively) and this was significantly different from the diameter of contemporary donor embryos (18.3, 14.3, and 13.0 microns, respectively). This is a swelling of 47, 91, and 109%, respectively. Since the degree of nuclear swelling does not appear to be related to cytoplasmic volume it is concluded that the components mediating nuclear swelling are not in a limiting supply.     

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).