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.     

6-DMAP诱导PM胚胎形成过程中核纤层蛋白B的动力学变化

我们的前期研究发现:被微管抑制剂nocodazole抑制在第一次有丝分裂中期的小鼠受精卵在加入6-DMAP处理后核膜重新出现,并且父、母本的基因组未发生融合,分别形成了类似雌、雄原核的两个细胞核,它们共存于卵细胞质中,我们把这种特殊的胚胎称之为PM胚胎(post-mitoticembryo)。本研究表明:在去除抑制剂3h后未能形成核膜的胚胎进一步卵裂,而形成核膜的PM胚胎培养24h未见进一步发育。此外,我们采用免疫荧光染色观察PM胚胎核膜重现过程中核纤层蛋白B的动力学变化,结果显示:在加入6-DMAP后核纤层蛋白B在染色体周围逐渐聚集,约3h后核膜完全形成,此时核纤层蛋白B在染色体周围的聚集达到最高峰。文中还对6-DMAP诱导核膜形成的机制进行了探讨。     

Nuclear transfer: Progress and quandaries

Cloning mammals by nuclear transfer is a powerful technique that is quickly advancing the development of genetically defined animal models. However, the overall efficiency of nuclear transfer is still very low and several hurdles remain before the power of this technique will be fully harnessed. Among these hurdles include an incomplete understanding of biologic processes that control epigenetic reprogramming of the donor genome following nuclear transfer. Incomplete epigenetic reprogramming is considered the major cause of the developmental failure of cloned embryos and is frequently associated with the disregulation of specific genes. At present, little is known about the developmental mechanism of reconstructed embryos. Therefore, screening strategies to design nuclear transfer protocols that will mimic the epigenetic remodeling occurring in normal embryos and identifying molecular parameters that can assess the developmental potential of pre-implantation embryos are becoming increasingly important. A crucial need at present is to understand the molecular events required for efficient reprogramming of donor genomes after nuclear transfer. This knowledge will help to identify the molecular basis of developmental defects seen in cloned embryos and provide methods for circumventing such problems associated with cloning the future application of this technology.     

Complete replacement of the mitochondrial genotype in a Bos indicus calf reconstructed by nuclear transfer to a Bos taurus oocyte

Due to the exclusively maternal inheritance of mitochondria, mitochondrial genotypes can be coupled to a particular nuclear genotype by continuous mating of founder females and their female offspring to males of the desired nuclear genotype. However, backcrossing is a gradual procedure that, apart from being lengthy, cannot ascertain that genetic and epigenetic changes will modify the original nuclear genotype. Animal cloning by nuclear transfer using host ooplasm carrying polymorphic mitochondrial genomes allows, among other biotechnology applications, the coupling of nuclear and mitochondrial genotypes of diverse origin within a single generation. Previous attempts to use Bos taurus oocytes as hosts to transfer nuclei from unrelated species led to the development to the blastocyst stage but none supported gestation to term. Our aim in this study was to determine whether B. taurus oocytes support development of nuclei from the closely related B. indicus cattle and to examine the fate of their mitochondrial genotypes throughout development. We show that indicus:taurus reconstructed oocytes develop to the blastocyst stage and produce live offspring after transfer to surrogate cows. We also demonstrate that, in reconstructed embryos, donor cell-derived mitochondria undergo a stringent genetic drift during early development leading, in most cases, to a reduction or complete elimination of B. indicus mtDNA. These results demonstrate that cross-subspecies animal cloning is a viable approach both for matching diverse nuclear and cytoplasmic genes to create novel breeds of cattle and for rescuing closely related endangered cattle.     

兔核移植胚胎蛋白质变化的电泳分析

采用ＳＤＳ－聚丙烯酰胺凝胶电泳及银染法,对兔核移植胚胎蛋白质合成类型的变化进行了研究。结果表明,“原核”期核移植胚胎中有几种蛋白质与核供体桑椹胚及受体卵母细胞的蛋白质类型明显不同,与同期受精卵中蛋白质类型相似,但在某些带上也有质或量的差别。结果提示,供体核基因表达被卵母细胞质所重排,但并非很完全。本文还对提高兔核移植胚胎发育能力可能的途径进行了讨论。     

Nuclei of oocytes derived from mouse parthenogenetic embryos are competent to support development to term

Mouse parthenotes result in embryonic death before 10 days of gestation, but parthenogenetic embryos (ng/fg PE) that contain haploid sets of genomes from nongrowing (ng) oocytes derived from newborn fetuses and fully grown (fg) oocytes derived from adults can develop into 13.5-day-old fetuses. This prolonged development is due to a lack of genomic imprinting in ng oocytes. Here, we show maternal genomes of oocytes derived from ng/fg PE are competent to support normal development. After 28 days of culture, the ovaries from ng/fg PE grew as well as the controls, forming vesicular follicles with follicular antrums. The oocytes collected from the developed follicles were the same size as those of the controls. To determine whether maternal primary imprinting had been established in the oocytes derived from ng/fg PE, we examined the DNA methylation status in differentially methylated regions of three imprinted genes, Igf2r, Lit1, and H19. The results showed that maternal-specific modifications were imposed in the oocytes derived from ng/fg PE. Further, to assess nuclear competence to support development, we constructed matured oocytes containing a haploid genome derived from ng/fg PE oocytes by serial nuclear transfer. After in vitro fertilization and culture and embryo transplantation into recipients, two live pups were obtained. One developed normally to a fertile adult. These results revealed that oocytes derived from ng/fg PE can be normally imprinted during oogenesis and acquire competence to participate in development as female genomes.     

Nuclear transplantation in the mouse: heritable differences between parental genomes after activation of the embryonic genome

Paternal and maternal genomes apparently have complementary roles during embryogenesis in the mouse, and both are essential for development to term. However, there is no direct evidence to show that functional differences between parental genomes remain intact after activation of the embryonic genome at the 2-cell stage. In this study we demonstrate that transfer of paternal or maternal nuclei from early haploid preimplantation embryos back to fertilized eggs from which one pronucleus was removed resulted in development to term, but only if the remaining pronucleus was of the parental type opposite to the donor nucleus. Hence, functional differences between parental chromosomes are heritable and they survive activation of the embryonic genome and probable reprogramming of donor embryonic nuclei by epigenetic factors in the egg cytoplasm.     

正常胚胎与核移植重构胚发育中的生物学变化比较

本文介绍了正常胚胎和核移植重构胚发育过程中的生物学变化,从细胞形态学和分子机理两方面阐述了二者之间的差异,总结了影响核移植重构胚胎发育的主要因素。在细胞形态学上着重探讨了卵子染色体结构变化对于卵重编程作用的影响,在分子水平上对卵子组蛋白与供核细胞组蛋白的置换进行了讨论,理论上为核移植效率的提高提供了借鉴。     

Excision of selectable genes from transgenic goat cells by a protein transducible TAT-Cre recombinase

The Cre/loxP site-specific recombination system is a widely used tool for genetic engineering of mammalian genomes. Recombination of loxP-modified alleles is often induced by introduction of foreign DNA vector expressing Cre into the cells. But the introduced DNA vector has the potential to integrate into the genome of the cells and continuous expression of Cre recombinase from the foreign vector has the potential to yield cytotoxicity and genotoxicity in various cells. In this study, we investigate the possibility of overcoming this limitation by using a cell-permeable TAT-Cre recombinase. We found that TAT-Cre treatment of transgenic goat fibroblast cells did not compromise the development competency of reconstructed embryos by using these TAT-Cre-treated cells as nuclear donor in nuclear transfer. Finally, we obtained two live cloned goats where a selectable gene cassette was removed. Our work not only provided an efficient protein transduction-based system for removing selectable genes from transgenic goats, but also presented strong evidence that no severe damage was made to the host cells during the process of protein transduction.     

Ratio of the zygote cytoplasm to the paternal genome affects the reprogramming and developmental efficiency of androgenetic embryos

Uniparental embryos have uniparental genomes and are very useful models for studying the specific gene expression of parents or for exploring the biological significance of genomic imprinting in mammals. However, the early developmental efficiency of androgenetic embryos is significantly lower than that of parthenogenetic embryos. In addition, oocytes are able to reprogram sperm nuclei after fertilization to guarantee embryonic development by maternally derived reprogramming factors, which accumulate during oogenesis. However, the importance of maternal material in the efficiency of reprogramming the pronucleus of androgenetic embryos is not known. In this study, androgenetic embryos were constructed artificially by pronucleus transfer (PT) or double sperm injection (DS). Compared with DS embryos, PT embryos that were derived from two zygotes contained more maternal material, like 10–11 translocation methylcytosine deoxygenase 3 (Tet3) and histone variant 3.3 (H3.3). Our experiments confirmed the better developmental potential of PT embryos, which had higher blastocyst rates, a stronger expression of pluripotent genes, a lower expression of apoptotic genes, and superior blastocyst quality. Our findings indicate that the aggregation of more maternal materials in the paternal pronucleus facilitate the reprogramming of the paternal genome, improving embryonic development in PT androgenesis.     

The developmental competence of bovine nuclear transfer embryos derived from cow versus heifer cytoplasts

Due to its economic importance, the production of cattle by nuclear transfer has been a primary research focus for many researchers during the past few years. While many groups have successfully produced cattle by nuclear transfer, and progress in this area continues, nuclear transfer remains a very inefficient technology. This study evaluates the effect of the oocyte source (cow and heifer) on the developmental competence of nuclear transfer embryos. In order for nuclear transfer to be successful, a differentiated donor cell must be reprogrammed and restored to a totipotent state. This reprogramming is probably accomplished by factors within the oocyte cytoplasm. This study indicates that oocytes derived from cows have a greater capacity to reprogram donor cell DNA following nuclear transfer as compared to heifer oocytes based on in vitro development to the 2-cell stage and to the compacted morula/blastocyst stages. Nuclear transfer embryos derived from cow oocytes resulted in significantly higher rates of pregnancy establishment than embryos derived from heifer oocytes and resulted in higher pregnancy retention at 90 and 180 days and a greater number of term deliveries. Following delivery more calves derived from cow oocytes tended to be healthy and normal than those derived from heifer oocytes. The differences in developmental efficiency between nuclear transfer embryos derived from cow and heifer cytoplasts demonstrate that subtle differences in oocyte biology can have significant effects on subsequent development of nuclear transfer embryos.     

Replicative advantage and tissue-specific segregation of RR mitochondrial DNA between C57BL/6 and RR heteroplasmic mice

To investigate the interactions between mtDNA and nuclear genomes, we produced heteroplasmic maternal lineages by transferring the cytoplasts between the embryos of two mouse strains, C57BL/6 (B6) and RR. A total of 43 different nucleotides exist in the displacement-loop (D-loop) region of mtDNA between B6 and RR. Heteroplasmic embryos were reconstructed by electrofusion using a blastomere from a two-cell stage embryo of one strain and an enucleated blastomere from a two-cell stage embryo of the other strain. Equivalent volumes of both types of mtDNAs were detected in blastocyst stage embryos. However, the mtDNA from the RR strain became biased in the progeny, regardless of the source of the nuclear genome. The RR mtDNA population was very high in most of the tissues examined but was relatively low in the brain and the heart. An age-related increase of RR mtDNA was also observed in the blood. The RR mtDNAs in the reconstructed embryos and in the embryos collected from heteroplasmic mice showed a different segregation pattern during early embryonic development. These results suggest that the RR mtDNA has a replicative advantage over B6 mtDNA during embryonic development and differentiation, regardless of the type of nuclear genome.     

Experimental reconstruction of mouse eggs and embryos: an analysis of mammalian development

The scope of experimental approaches applicable to the study of mammalian eggs and embryos has advanced in recent years to provide unprecedented opportunities for understanding mammalian embryology. Amongst these significant advances has been the ability to alter the genetic constitution of eggs by pronuclear and nuclear transplantation as well as by the introduction of specific cloned genes into eggs and embryos. These techniques can be used in conjunction with the experimental reconstruction of preimplantation embryos to investigate more precisely a number of aspects of mammalian embryology. Recently, a most intriguing aspect of development has been uncovered, one that is apparently unique to mammals; experiments have revealed that the parental genomes are not functionally equivalent during embryogenesis. Hence, the parental origin of chromosomes determines their influence during embryogenesis. The mechanistic aspects responsible for the germ line modifications of homologous chromosomes, their role during development, and the wide-ranging implications of these findings for mammalian development have yet to be fully defined. An understanding of this process will provide the basis for developing genetic and reproductive strategies that can be applied to domestic animals and to humans.     

Diploid mouse embryos constructed at the late 2-cell stage from haploid parthenotes and androgenotes can develop to term

Male and female gamete nuclei are required to ensure the full-term development of the mouse embryo. Differential expression of the two genomes has been proposed as the basis for this requirement. In order to investigate whether some interactions between the paternal and the maternal genomes are essential before or at the time of the activation of the embryonic genome, we have constructed diploid embryos from haploid parthenotes and androgenotes at the late 2-cell stage. These embryos developed to term into normal offsprings. This shows that the male and the female genomes can be activated separately and are still able to ensure complete development when put together in cytoplasm synchronized with the nuclei. These experiments also show that the egg cytoplasm does not need any male contribution before the late 2-cell stage.     

Autophagy and apoptosis: parent-of-origin genome-dependent mechanisms of cellular self-destruction

Functional genomic imprinting is necessary for the transfer of maternal resources to mammalian embryos. Imprint-free embryos are unable to establish a viable placental vascular network necessary for the transfer of resources such as nutrients and oxygen. How the parental origin of inherited genes influences cellular response to resource limitation is currently not well understood. Because such limitations are initially realized by the placenta, we studied how maternal and paternal genomes influence the cellular self-destruction responses of this organ specifically. Here, we show that cellular autophagy is prevalent in androgenetic (i.e. having only a paternal genome) placentae, while apoptosis is prevalent in parthenogenetic (i.e. having only a maternal genome) placentae. Our findings indicate that the parental origin of inherited genes determines the placenta''s cellular death pathway: autophagy for androgenotes and apoptosis for parthenogenotes. The difference in time of arrest between androgenotes and parthenogenotes can be attributed, at least in part, to their placentae''s selective use of these two cell death pathways. We anticipate our findings to be a starting point for general studies on the parent-of-origin regulation of autophagy. Furthermore, our work opens the door to new studies on the involvement of autophagy in pathologies of pregnancy in which the restricted transfer of maternal resources is diagnosed.     

Interspecies nuclear transfer reveals that demethylation of specific repetitive sequences is determined by recipient ooplasm but not by donor intrinsic property in cloned embryos

DNA methylation/demethylation of donor genomes in recipient ooplasm after nuclear transfer occurs in a species-specific way. In cloned rabbit and bovine embryos, repetitive sequences maintain the donor-type methylation status, but typical demethylation of repetitive sequences takes place in cloned porcine embryos. To clarify whether the demethylation is controlled by donor nucleus intrinsic property or by recipient ooplasm, we used interspecies somatic cell nuclear transfer (iSCNT) model to examine the methylation status of repetitive sequences in pig-to-rabbit and rabbit-to-pig interspecies embryos. We found that no demethylation of pig repetitive sequences was observed in pig-to-rabbit iSCNT embryos, while the examined rabbit repetitive sequence Rsat IIE was demethylated in rabbit-to-pig iSCNT embryos. These results indicate that demethylation of donor repetitive sequences is determined by ooplasm but not by donor intrinsic property and that ooplasm from different species have different capabilities to demethylate genes.     

Nucleolar ultrastructure in bovine nuclear transfer embryos

Nuclear transfer experiments in mammals have attempted to reprogram a donor nucleus to a state equivalent to the zygotic one. Reprogramming of the donor nucleus is, among other features, indicated by a synthesis of ribosomal RNA (rRNA). The initiation of rRNA synthesis is simultaneously reflected in nuclear morphology as a transformation of the nucleolus precursor body into a functional rRNA synthesising nucleolus with a characteristic ultrastructure. We examined nucleolar ultrastructure in bovine in vitro produced (control) embryos and in nuclear transfer embryos reconstructed from a MII phase (nonactivated) or S phase (activated) cytoplasts. Control embryos were fixed at the two-, four-, early eight- and late eight-cell stages; nuclear transfer embryos were fixed at 1 and 3 hr post fusion and at the two-, four-, and eight-cell stages. Control embryos possessed a nucleolar precursor body throughout all three cell cycles. In the eight-cell stage embryo, a primary vacuole appeared as an electron lucid area originating in the centre of the nucleolar precursor body. In nuclear transfer embryos reconstructed from nonactivated cytoplasts, the nuclear envelope was fragmented or completely broken down at 1 hr after fusion and, by 3 hr after fusion, it was restored again. At this time, the reticulated fibrillo-granular nucleolus had an almost round shape. The nucleolar precursor body seen in the two-cell stage nuclear transfer embryos consisted of intermingled filamentous components and secondary vacuoles. A nucleolar precursor body typical for the two-cell stage control embryos was never observed. None of the reconstructed embryos of this group reached the eight-cell stage. Nuclear transfer embryos reconstructed from activated cytoplasts, in contrast, exhibited a complete nuclear envelope at all time intervals after fusion. In the two-cell stage nuclear transfer embryo, the originally reticulated nucleolus of the donor blastomere had changed into a typical nucleolar precursor body consisting of a homogeneous fibrillar structure. A primary vacuole appeared in the four-cell stage nuclear transfer embryos, which was one cell cycle earlier than in control embryos. Only nuclear transfer embryos reconstructed from activated cytoplasts underwent complete remodelling of the nucleolus. The reorganisation of the donor nucleolar architecture into a functionally active nucleolus was observed as early as in the four-cell stage nuclear transfer embryo. These ultrastructural observations were correlated with our autoradiographic data on the initiation of RNA synthesis in nuclear transfer embryos.     

Micromanipulation of mammalian embryos: Principles, progress and future possibilities

Numerous advances in development of techniques for manipulating mammalian embryos outside the maternal environment have been made over the past decade. Some techniques were developed primarily for use in research; others were developed in response to problems of practical livestock production but have proven useful in research as well. Embryo micromanipulation procedures are used often in conjunction with embryo transfer, and interest in these procedures was stimulated by growth of the embryo transfer industry. Included in this review are discussions of procedures for manipulation of gametes and embryos, including sperm injection into oocytes, pronuclear and nuclear transfer, embryo biopsy and splitting, experimental chimera production and isolation of embryonic stem cells.     

Bovine somatic cell nuclear transfer using recipient oocytes recovered by ovum pick-up: effect of maternal lineage of oocyte donors.

The efficiency of bovine nuclear transfer using recipient oocytes recovered by ultrasound-guided follicle aspiration (ovum pick-up [OPU]) was investigated. Oocyte donors were selected from 2 distinct maternal lineages (A and B) differing in 11 nucleotide positions of the mitochondrial DNA control region. A total of 1342 cumulus-oocyte complexes (COCs) were recovered. The numbers of total COCs and class I/II COCs recovered from donors of lineage A were higher (P < 0.001) than those obtained from lineage B. Follicle aspiration once per week yielded a higher (P < 0.001) total number of COCs per session than aspiration twice per week, whereas the reproduction status of donors (heifer vs. cow) had no effect on OPU results. Of the 1342 oocytes recovered, 733 (55%) were successfully matured in vitro and used for nuclear transfer. Fusion was achieved in 550 (75%) karyoplast-cytoplast complexes (KCCs), resulting in 277 (50%) cleaved embryos on Day 3. On Day 7 of culture, 84 transferable embryos (15% based on fused KCCs) were obtained. After 38 transfers (10 single, 22 double, and 6 triple transfers), 9 recipients (8 double and 1 triple transfer) were diagnosed as pregnant on Day 28, corresponding to a pregnancy rate of 24%. The proportion of transferable embryos on Day 7 was significantly (P < 0.05) influenced by maternal lineage of oocyte donors and by the frequency of follicle aspiration. Our study demonstrates the feasibility of generating nuclear transfer embryos with defined cytoplasmic background. These will be valuable tools to experimentally dissect the effects of nuclear and cytoplasmic components on embryonic, fetal, and postnatal development.