in vitro development of porcine enucleated oocytes reconstructed by the transfer of porcine fetal fibroblasts and cumulus cells

In the pig little information is available on cytoplasmic events during the reprogramming of oocytes reconstructed with somatic nuclei. The present study was conducted to determine the developmental potential of porcine cumulus cells (CC) and fetal fibroblasts (FF) after they were transferred into enucleated oocytes. Non-quiescent FF were fused to the enucleated oocytes using electrical pulse, whereas CC were directly injected into the oocytes. Transferred nuclei from both CC and FF underwent premature chromosome condensation (PCC), nuclear swelling and pronucleus formation. The remodeled oocytes developed to the mitotic and 2-cell stage at 18 to 24 h after nuclear transfer. The pattern of nuclear remodeling was similar regardless of the sources of karyoplasts or nuclear transfer methods. However, using FF, 24% of nuclear transferred embryos developed to the morula or blastocyst stage, whereas only 8% of those using CC developed to the morula or blastocyst stage. These results suggest that porcine oocyte cytoplasm can successfully reprogram somatic cell nuclei and support the development of nuclear transferred embryos to the blastocyst stage.     

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。     

Role of histone acetylation in reprogramming of somatic nuclei following nuclear transfer

Before fertilization, chromatins of both mouse oocytes and spermatozoa contain very few acetylated histones. Soon after fertilization, chromatins of both gametes become highly acetylated. The same deacetylation-reacetylation changes occur with histones of somatic nuclei transferred into enucleated oocytes. The significance of these events in somatic chromatin reprogramming to the totipotent state is not known. To investigate their importance in reprogramming, we injected cumulus cell nuclei into enucleated mouse oocytes and estimated the histone deacetylation dynamics with immunocytochemistry. Other reconstructed oocytes were cultured before and/or after activation in the presence of the highly potent histone deacetylase inhibitor trychostatin A (TSA) for up to 9 h postactivation. The potential of TSA-treated and untreated oocytes to develop to the blastocyst stage and to full term was compared. Global deacetylation of histones in the cumulus nuclei occurred between 1 and 3 h after injection. TSA inhibition of histone deacetylation did not affect the blastocyst rate (37% with and 34% without TSA treatment), whereas extension of the TSA treatment beyond the activation point significantly increased the blastocyst rate (up to 81% versus 40% without TSA treatment) and quality (on average, 59 versus 45 cells in day 4 blastocysts with and without TSA treatment, respectively). TSA treatment also slightly increased full-term development (from 0.8% to 2.8%). Thus, deacetylation of somatic histones is not important for reprogramming, and hyperacetylation might actually improve reprogramming.     

Cell synchronization for the purposes of nuclear transfer in the bovine

We have examined the reprogramming ability of donor fibroblast nuclei in various phases of the cell cycle, upon transfer to cytoplasts, using a bovine nuclear transfer (NT) model. Bovine fetal fibroblasts were cultured in reduced serum and conditioned medium to induce quiescence (G0) and treated with nocodazole to induce M phase arrest. Unsynchronized actively dividing cells (control) were mainly in G1. Cells synchronized in G0, M, and G1 phase were transferred to enucleated bovine MII oocytes by direct injection using the Piezo-Drill microinjector. NT oocytes were artificially activated following injection. Cells at the M phase were also transferred to enucleated oocytes after artificial activation. Cells induced into quiescence by serum starvation and unsynchronized donor cells produced the highest rates of development to the morula/blastocyst stage (20% and 18%, respectively). Development to blastocyst was significantly higher in parthenogenetic controls compared to NT embryos. The transfer of M phase nuclei to MII cytoplasts was not associated with high development to the blastocyst stage. Nevertheless, determining the viability of these embryos requires transfer to recipient animals and assessment of in vivo development.     

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.     

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.     

The use ofXenopus oocytes and embryos as a route towards cell replacement

When nuclei of somatic cells are transplanted to enucleated eggs ofXenopus, a complete reprogramming of nuclear function can take place. To identify mechanisms of nuclear reprogramming, somatic nuclei can be transplanted to growing meiotic oocytes ofXenopus, and stem cell genes activated without DNA replication. The combination of somatic cell nuclear transfer with morphogen signalling and the community effect may lead towards the possibility of cell replacement therapy. When mechanisms of nuclear reprogramming are understood, it may eventually be possible to directly reprogramme human somatic cell nuclei without the use of eggs.     

Changes in embryonic 8-cell nuclei transferred by means of cell fusion to mouse eggs.

Metaphase II and activated mouse oocytes were fused with 8-cell blastomeres, and morphological changes in the transferred nuclei were followed using light and electron microscopy. In metaphase II oocytes, blastomere nuclei underwent premature chromosome condensation (PCC) typical for S-phase nuclei: chromatin pulverization. Then an abortive spindle was formed without evident microtubule organizing centers. Blastomere chromosomes condensed to a lesser degree than meiotic chromosomes and lacked mature functional, trilaminar kinetochores. After parthenogenetic activation of these oocytes, blastomere chromosomes followed, in synchrony with oocyte chromatin, a similar route of changes (anaphase, telophase) and then reformed interphase nuclei of the pronuclear type. Remodeling of 8-cell nucleus thus occurred, but the integrity of the chromatin set was frequently disturbed by formation of micronuclei. If blastomere fusion with oocytes was done close to activation (either before or after parthenogenetic stimulation), the chances of remodeling of the nuclei decreased, because PCC was not regularly induced in all oocytes. In hybrids produced 60 min or later after oocyte activation, blastomere nuclei were maintained in interphase without any structural modifications. Multiple experiments in the mouse have shown that the nuclei from 8-cell stage transferred to enucleated oocytes and egg cells are not capable of substituting for pronuclear functions. Possible reasons for impaired functional reprogramming of 8-cell nucleus in the mouse are discussed in light of our present findings on the morphology of nuclei transferred before and after oocyte activation.     

Factors influencing chromosome condensation and development of cloned rat embryos

Factors influencing premature chromosome condensation (PCC) in transferred rat nuclei have been examined. Chromosome condensation of rat cumulus cell nuclei did not occur when the cell nuclei were injected into enucleated rat oocytes. By contrast, chromosome condensation did occur after transfer to enucleated mouse oocytes or intact rat oocytes. In the first serial NT experiment, rat somatic cell nuclei were injected into enucleated mouse oocytes, and the reconstructed oocytes were activated by strontium chloride. From these reconstructed embryos, karyoplasts containing pronucleus-like vesicles were transferred into pronuclear zygote-derived cytoplasts by a DC pulse. Transfer of a total of 340 serial NT zygotes into recipient females, including 206 two-cell embryos, resulted in only seven implantation sites. In the second serial NT experiment, rat somatic cell nuclei were injected into intact rat oocytes; the recipient metaphase-plate was then aspirated under UV light from the NT oocytes in which PCC of injected nuclei was observed. After activation of the NT oocytes, karyoplasts were introduced into zygote-derived cytoplasts. Transfer of a total of 115 serial NT zygotes, including 37 two-cell embryos, resulted in four implantation sites but no live offspring. These results establish a mean of inducing chromosome condensation in rat oocytes and demonstrate that reconstructed rat zygotes can be prepared by serial NT procedures. Developmental competence of these embryos remains to be clarified.     

Nuclear transplantation in early pig embryos

Nuclear transfer was evaluated in early porcine embryos. Pronuclear stage embryos were centrifuged, treated with cytoskeletal inhibitors, and subsequently enucleated. Pronuclei containing karyoplasts were placed in the perivitelline space of the enucleated zygote and fused to the enucleated zygote with electrofusion. The resulting pronuclear exchange embryos were either monitored for cleavage in vitro (9/13 cleaved and contained 2 nuclei after 24 h, 69%) or for in vivo development. In vivo development after 3 days resulted in 14/15 (93%) of the embryos transferred cleaving to the greater than or equal to 4-cell stage and after 7 days 6/16 (38%) reaching the expanded blastocyst stage. A total of 56 pronuclear exchange embryos were allowed to go to term, and 7 piglets were born. A similar manipulation procedure was used to transfer 2-, 4- or 8-cell nuclei to enucleated, activated meiotic metaphase II oocytes. Enucleation was effective in 74% (36/49) of the contemporary oocytes. Activation was successful in 81% (37/46) of nonmanipulated but pulsed oocytes versus 13% (4/31) of control oocytes (p less than 0.01). After 6 days in vivo, 9% (1/11) of the 2-cell nuclei, 8% (7/83) of the 4-cell nuclei, and 19% (11/57) of the 8-cell nuclei transferred to enucleated, activated meiotic metaphase II oocytes resulted in development to the compact morula or blastocyst stage (p less than 0.01). A total of 88 nuclear transfer embryos were transferred to recipient gilts for continued development. A single piglet was born after the transfer of a 4-cell nucleus to an enucleated, activated metaphase II oocyte and subsequent in vivo development.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of age of cell donors of nuclei on effectivness of developing cloned rabbit embryos]

We studied the capacity of nuclei of rabbit fibroblasts taken from various developmental stages for reprogramming in the cytoplasm of mature aging enucleated oocytes and development of the cloned embryos to the preimplantation stages. A negative correlation was found between the age of an animal--donor of fibroblasts and efficiency of the development of cloned embryos (rmorula-blastocyst = -0.826, rblastocyst = -0.7139). A reliably decreased capacity for reprogramming of the nuclei of donor fibroblasts was shown upon transition from prenatal development to the postnatal one, as well as a trend to a decreased capacity of nuclei for reprogramming during aging. Aging of cells in the culture, at least until the 10th passage, did not affect the capacity of the nuclei of fetal fibroblasts for reprogramming and development of cloned embryos.     

Reprogramming mediated by stem cell fusion

Advances in mammalian cloning prove that somatic nuclei can be reprogrammed to a state of totipotency by transfer into oocytes. An alternative approach to reprogram the somatic genome involves the creation of hybrids between somatic cells and other cells that contain reprogramming activities. Potential fusion partners with reprogramming activities include embryonic stem cells, embryonic germ cells, embryonal carcinoma cells, and even differentiated cells. Recent advances in fusion-mediated reprogramming are discussed from the standpoints of the developmental potency of hybrid cells, genetic and epigenetic correlates of reprogramming, and other aspects involved in the reprogramming process. In addition, the utility of fusion-mediated reprogramming for future cell-based therapies is discussed.     

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.     

Age-Related Effect of Cells as Donors of Nuclei: On the Efficiency of the Development of Cloned Rabbit Embryos

We studied the capacity of the nuclei of rabbit fibroblasts taken from various developmental stages for reprogramming in the cytoplasm of mature aging enucleated oocytes and the development of the cloned embryos to the preimplantation stages. A negative correlation was found between the age of an animal donor of fibroblasts and the efficiency of the development of cloned embryos (r _{morula-blastocyst}= –0.826, r _blastocyst= –0.7139). A reliably decreased capacity for reprogramming of the nuclei of donor fibroblasts was shown upon the transition from prenatal development to postnatal development, as well as a trend to a decreased capacity of nuclei for reprogramming during aging. The aging of cells in the culture, at least until the tenth passage, did not affect the capacity of the nuclei of fetal fibroblasts for reprogramming and the development of cloned embryos.     

Haploid maternal genome derived from early diplotene oocytes can substitute for the female pronucleus in preimplantation mouse development

We describe the preimplantation development of mouse embryos that have received the haploid maternal genome derived from early diplotene nuclei of primordial oocytes (PO). Two generations of recipient egg-cells were used. Induction of two meiotic divisions of the PO nucleus and the reduction of the number of chromosomes to the haploid level were achieved in preovulatory oocytes (primary recipients). The developmental potential of the obtained haploid genome was examined in zygotes (secondary recipients). The nuclei of PO obtained from newborn mice were transferred by cell electrofusion to in vitro maturing (IVM) and enucleated preovulatory mouse oocytes. The reconstructed oocytes which had completed maturation, i.e., reached metaphase II, were artificially activated (8% ethanol + CHX). Activated oocytes were used as donors of haploid pronuclei of PO origin which were transferred (by karyoplast fusion) to partially enucleated zygotes containing only the male pronucleus. Thus, reconstituted zygotes were transplanted to the ligated oviducts of the cycling mice and 27% of them developed to the blastocyst stage. Our experiments demonstrate that 1) the nucleus of PO can be induced to premature meiotic divisions in an IVM enucleated preovulatory oocyte; 2) in the presence of a normal male pronucleus, the haploid pronucleus of PO origin can substitute for a female pronucleus during preimplantation development. Mol. Reprod. Dev. 48:488–495, 1997. © 1997 Wiley-Liss, Inc.     

Genetic reprogramming following nuclear transplantation in Amphibia.

Specialized cells are generally unable to switch from one type to another. For example, muscle cells can not be converted to intestine, brain, skin, etc. However, the nucleus of a specialized cell, such as muscle, can be transplanted to an enucleated egg, and the resulting combination will form all these and most other cell types. Likewise somatic cell nuclei injected into oocytes will switch their pattern of gene expression to conform to that of an oocyte, repressing some genes and activating others. This article reviews what is known of the mechanisms involved in these examples of nuclear reprogramming.     

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.     

Heterogeneous nuclear transfer embryos reconstructed by bovine oocytes and camel (Camelus bactrianus) skin fibroblasts and their subsequent development

Summary This study reconstructed heterogeneous embryos using camel skin fibroblast cells as donor karyoplasts and the bovine oocytes as recipient cytoplasts to investigate the reprogramming of camel somatic cell nuclei in bovine oocyte cytoplasm and the developmental potential of the reconstructed embryos. Serum-starved skin fibroblast cells, obtained from adult camel, were electrically fused into enucleated bovine metaphase II (MII) oocytes that were matured in vitro. The fused eggs were activated by Inomycin with 2 mM/ml 6-dimethylaminopurine. The activated reconstructed embryos were cocultured with bovine cumulus cells in synthetic oviduct fluid supplemented with amino acid (SOFaa) and 10% fetal calf serum for 168 h. Results showed that 53% of the injected oocytes were successfully fused, 34% of the fused eggs underwent the first egg cleavage, and 100% of them developed to four- or 16-cell embryo stages. The first completed cleavage of xenonuclear transfer camel embryos occurred between 22 and 48 h following activation. This study demonstrated that the reconstructed embryos underwent the first embryonic division and that the reprogramming of camel fibroblast nuclei can be initiated in enucleated bovine MII oocytes.     

Effect of telophase enucleation on bovine somatic nuclear transfer

Telophase enucleation has been proven to be an efficient method for preparing recipient cytoplasts in bovine embryonic nuclear transfer (2, 11). This research was designed to study in vitro development of bovine oocytes containing transferred somatic cell nuclei, reconstructed by using enucleated in vitro-matured oocytes 32 h of age at telophase II stage as recipient cytoplasts, compared with those 24 h of age at metaphase II stage. Two protocols for donor cell injection were adopted, i.e., subzonal injection (SUZI) and intracytoplasmic injection (ICI). Bovine oviduct epithelial cells (BOECs) and bovine cumulus cells (BCCs) from an adult cow were used as nuclear donors for these experiments. In SUZI groups, the fusion rate of donor cells, both BOECs and BCCs, with MII enucleated oocytes were higher than those with TII enucleated oocytes (54% vs. 41% and 53% vs. 39%, respectively; P<0.05), but the development rates to morula plus blastocyst stage in MII groups were lower than those in TII groups (22% vs. 39% and 21% vs. 41%, respectively; P<0.05). In ICI groups, about 26% of enucleated MII oocytes injected with BOECs or BCCs cleaved and only small parts of them developed to blastocyst stage (4% and 3%, respectively; P>0.05). When BOECs or BCCs were intracytoplasmically injected into oocytes enucleated at TII stage, no blastocyst was formed in either donor cell group and no cleavage occurred in BOEC group. Our data demonstrated that telophase enucleation is beneficial to early embryo development when bovine somatic nuclei are transferred by subzonal injection. However, it is harmful when donor cells are directly injected into the cytoplast of the enucleated oocytes.