Cloning of Asian yellow goat (C. hircus) by somatic cell nuclear transfer: telophase enucleation combined with whole cell intracytoplasmic injection

Our and other previous studies have shown that telophase enucleation is an efficient method for preparing recipient cytoplasts in nuclear transfer. Conventional methods of somatic cell nuclear transfer either by electro-fusion or direct nucleus injection have very low efficiency in animal somatic cell cloning. To simplify the manipulation procedure and increase the efficiency of somatic cell nuclear transfer, this study was designed to study in vitro and in vivo development of Asian yellow goat cloned embryos reconstructed by direct whole cell intracytoplasmic injection (WCICI) into in vitro matured oocytes enucleated at telophase II stage. Our results demonstrated that the rates of cleavage and blastocyst development of embryos reconstructed by WCICI were slightly higher than in conventional subzonal injection (SUZI) group, but no statistic difference (P > 0.05) existed between these two methods. However, the percentage of successful embryonic reconstruction in WCICI group was significantly higher than that in SUZI group (P < 0.05). After embryo transfer at 4-cell stage, the foster in both groups gave birth to offspring. Therefore, the present study suggests that the telophase ooplasm could properly reprogram the genome of somatic cells, produce Asian yellow goat cloned embryos and viable kids, and whole cell intracytoplasmic injection is an efficient protocol for goat somatic cell nuclear transfer.     

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.     

The effects of chemical enucleation combined with whole cell intracytoplasmic injection on panda-rabbit interspecies nuclear transfer

Conventional methods of somatic cell nuclear transfer either by electrofusion or direct nucleus injection have very low efficiency in animal cloning, especially interspecies cloning. To increase the efficiency of interspecies somatic cell nuclear transfer, in the present study we introduced a method of whole cell intracytoplasmic injection (WCICI) combined with chemical enucleation into panda-rabbit nuclear transfer and assessed the effects of this method on the enucleation rate of rabbit oocytes and the in vitro development and spindle structures of giant panda-rabbit reconstructed embryos. Our results demonstrated that chemical enucleation can be used in rabbit oocytes and the optimal enucleation result can be obtained. When we compared the rates of cleavage and blastocyst formation of subzonal injection (SUZI) and WCICI using chemically enucleated rabbit oocytes as cytoplasm recipients, the rates in the WCICI group were higher than those in the SUZI group, but there was no statistically siginificant difference (p > 0.05) between the two methods. The microtubule structures of rabbit oocytes enucleated by chemicals and giant panda-rabbit embryos reconstructed by WCICI combined with chemical enucleation were normal. Therefore the present study suggests that WCICI combined with chemical enucleation can provide an efficient and less labor-intensive protocol of interspecies somatic cell nuclear transfer for producing giant panda cloned embryos.     

Interspecies nuclear transfer of Tibetan antelope using caprine oocyte as recipient

Interspecies nuclear transfer is an invalulable tool for studying nucleus-cytoplasm interactions; and at the same time, it provides a possible alternative to clone endangered animals whose oocytes are difficult to obtain. In the present study, we investigated the possibility of cloning Tibetan antelope embryos using abattoir-derived caprine oocytes as recipients. Effects of culture conditions, enucleation timing, and donor cell passages on the in vitro development of Tibetan antelope-goat cloned embryos were studied. Maternal to zygotic transition timing of interspecies Tibetan antelope embryos was also investigated using two types of cloned embryos, Tibetan antelope-rabbit and Tibetan antelope-goat embryos. Our results indicate that: (1) goat oocyte is able to reprogram somatic cells of different genus and supports development to blastocyst in vitro. (2) Coculture system supported the development of Tibetan antelope-goat embryos to blastocyst rate stage (4.0%), while CR1aa alone did not. (3) When MII phase enucleated caprine cytoplast and TII phase enucleated caprine cytoplast were used as recipients, the fusion rate and blastocyst rate of hybrid embryos were not statistically different (73.9% vs. 67.4%; 4.0% vs. 1.1%). (4) When donor cells at 3-8 passages were used, 2.9% hybrid embryos developed to blastocysts, while none developed to blastocysts when cells at 10-17 passages were used. (5) There may be a morula-to-blastocyst block for Tibetan antelope-goat, while there may be an 8- to 16-cell block for Tibetan antelope-rabbit embryos.     

Production of cloned bovine embryos by somatic cell transfer into enucleated zona-free oocytes

Cloned bovine embryos were produced at the blastocyst stage. Prior to enucleation, oocytes were freed from the zona pellucida. Fibroblasts isolated from the bovine fetus were used as nuclear donors. Pairs of fetal fibroblasts and enucleated oocytes (cytoplasts) were glued in phytohemagglutinin solution under a binocular microscope. The subsequent electrofusion of 39 fetal fibroblast-cytoplast pairs yielded 36 reconstructed one-cell embryos (92.3%). After culturing in synthetic oviduct fluid for 7.5 days, seven cloned embryos developed to the blastocyst stage (19.4%) and six blastocysts were considered fit for transplantation. The applied technique of bovine embryo growth allowed 31.1% zona-free oocytes parthenogenetically activated by to reach the blastocyst stage.     

Effects of enucleation and caffeine on maturation-promoting factor (MPF) and mitogen-activated protein kinase (MAPK) activities in ovine oocytes used as recipient cytoplasts for nuclear transfer

In general, oocytes arrested at metaphase of the second meiotic division (MII) are used as recipient cytoplasts for nuclear transfer (NT) procedures. MII oocytes contain high levels of maturation-promoting factor (MPF) and mitogen-activated protein kinase (MAPK), which cause nuclear envelope breakdown (NEBD) and premature chromosome condensation (PCC) in the transferred nucleus and have been implicated in nuclear reprogramming. However, the occurrence of NEBD and the extent of PCC are variable between individual oocytes and species and are dependent on donor cell type and cell cycle stage. Enucleation, which removes oocyte cytoplasm, may reduce MPF and MAPK activities and reduce reprogramming; conversely, increasing kinase activities may increase reprogramming. We compared the effects of enucleation of ovine oocytes at anaphase/telophase of the first meiotic division (AI-TI) and at MII. MPF and MAPK activities were maximal at MII; blind enucleation at AI-TI was more efficient than at MII and removed a smaller volume of cytoplasm. Neither protocol significantly affected the activity of either kinase and the fate of the donor nucleus; however, enucleation per se significantly reduced the occurrence of NEBD in NT embryos. Treatment with 10 mM caffeine significantly increased the activities of both kinases and the occurrence of NEBD but did not affect the frequency of development to the blastocyst stage; however, a significant increase in total cell numbers was observed. The results show that caffeine can increase MPF and MAPK activities in ovine oocytes and that this may contribute to an increased reprogramming in NT 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.     

Bovine embryo cloning: Characterization of the recipient cytoplasts by phosphorylation patterns and kinase activities

When in vitro -matured oocytes were enucleated, aged and kept at 10°C before reconstitution, the in vitro development of nuclear transfer embryos to the blastocyst stage did not differ from that obtained with in vitro fertilization. This suggests that these recipient cytoplasts constitute a suitable environment for the development of the nuclear transplant. The aim of the present study was to investigate, at the biochemical level, the result of the preparation of recipient oocytes, including enucleation, ageing and cooling. For this purpose the phosphorylation profiles of four groups of in vitro -matured bovine oocytes (aged oocytes, aged-cooled oocytes, enucleated-aged oocytes and enucleated-aged-cooled oocytes (recipient cytoplasts)) were analyzed. These recipient cytoplasts exhibited a phosphorylation profile similar to that of activated oocytes. Maturation promoting factor (MPF) activity, which was high in young metaphase II oocytes, in aged oocytes, in enucleated-aged oocytes and in aged-cooled oocytes, dropped to the basal level in enucleated-aged-cooled oocytes (recipient cytoplasts), while mitogen-activated protein kinase (MAPK) activity remained elevated. The combination of enucleation, ageing and cooling following oocyte in vitro maturation resulted in an interphase-like stage cytoplasm having a phosphorylation profile and low MPF activity similar to activated oocytes, but exhibiting high MAPK activity.     

Hypertonic medium treatment for localization of nuclear material in bovine metaphase II oocytes

Oocytes enucleated at the second metaphase stage (MII) are often used as recipient cytoplasts for nuclear transfer. The oocyte's nuclear material has been traditionally removed blindly by aspirating the first polar body (Pb1) along with a portion of the cytoplasm. However, the Pb1-guided enucleation method is unreliable because the position of the Pb1 is variable. A previous study showed that pretreatment of mouse oocytes with 3% (0.09 M) sucrose allowed visualization of the metaphase spindle and chromosomes under standard light microscopy and led to a 100% enucleation rate. The same sucrose treatment, however, did not produce the same effect in bovine oocytes. In this study, we increased the concentration of sucrose to 0.3-0.9 M in PBS containing 20% fetal bovine serum (SPF) and found that the majority of the treated bovine oocytes (75%-86%) formed a small transparent bud into the perivitelline space, as compared with the 0.1 M sucrose (6%) or the no sucrose (0%) control groups. Staining of DNA with Hoechst 33342 revealed that these projections coincided with the position of the metaphase chromosomes in 100% of sucrose-treated oocytes, whereas only 31% of oocytes showed alignment of the position of Pb1 with their nuclear materials. Furthermore, 95% of oocytes treated in 0.3 M SPF were successfully enucleated by removing a small amount of cytoplasm adjacent to the projection. This is a significantly higher enucleation rate than that obtained by conventional Pb1-guided enucleation, even when a larger amount of cytoplasm was removed. For nuclear transfer, the enucleated oocytes treated with sucrose did not differ from the control oocytes in rates of fusion, cleavage, or development to blastocysts, or in the average cell numbers in blastocysts. This study demonstrated that 0.3 M sucrose treatment of bovine oocytes facilitates the localization of metaphase chromosomes under normal light microscopy and hence increases enucleation efficiency without compromising the in vitro development potential of cloned embryos by nuclear transfer.     

Chromosomes in the Porcine First Polar Body Possess Competence of Second Meiotic Division within Enucleated MII Stage Oocytes

To determine whether chromosomes in the porcine first polar body (PB1) can complete the second meiotic division and subsequently undergo normal pre-implantation embryonic development, we examined the developmental competence of PB1 chromosomes injected into enucleated MII stage oocytes by nuclear transfer method (chromosome replacement group, CR group). After parthenogenetic activation (PA) or in vitro fertilization (IVF), the cleavage rate of reconstructed oocytes in the IVF group (CR-IVF group, 36.4 ± 3.2%) and PA group (CR-PA group, 50.8 ± 4.2%) were significantly lower than that of control groups in which normal MII oocytes were subjected to IVF (MII-IVF group, 75.8 ± 1.5%) and PA (MII-PA group, 86.9 ± 3.7%). Unfertilized rates was significantly higher in the CR-IVF group (48.6 ± 3.3%) than in the MII-IVF group (13.1 ± 3.4%). The blastocyst formation rate was 8.3 ± 1.9% in the CR-PA group, whereas no blastocyst formation was observed in the CR-IVF group. To produce tetraploid parthenogenetic embryos, intact MII stage oocytes injected with PB1chromosomes were electrically stimulated, treated with 7.5 μg/mL cytochalasin B for 3 h (MII oocyte + PB1 + CB group), and then cultured without cytochalasin B. The average cleavage rate of reconstructed oocytes was 72.5% (48 of 66), and the blastocyst formation rate was 18.7% (9 of 48). Chromosome analysis showed similar proportions of haploid and diploid cells in the control (normal MII oocytes) and CR groups after PA; overall, 23.6% of blastocysts were tetraploid in the MII oocyte + PB1 + CB group. These results demonstrate that chromosomes in PB1 can participate in normal pre-implantation embryonic development when injected into enucleated MII stage oocytes, and that tetraploid PA blastocysts are produced (although at a low proportion) when PB1 chromosomes are injected into intact MII stage oocytes.     

Germinal vesicle material is essential for nucleus remodeling after nuclear transfer

Successful cloning by nuclear transfer has been reported with somatic or embryonic stem (ES) cell nucleus injection into enucleated mouse metaphase II oocytes. In this study, we enucleated mouse oocytes at the germinal vesicle (GV) or pro-metaphase I (pro-MI) stage and cultured the cytoplasm to the MII stage. Nuclei from cells of the R1 ES cell line were injected into both types of cytoplasm to evaluate developmental potential of resulting embryos compared to MII cytoplasmic injection. Immunocytochemical staining revealed that a spindle started to organize 30 min after nucleus injection into all three types of cytoplasm. A well-organized bipolar spindle resembling an MII spindle was present in both pro-MI and MII cytoplasm 1 h after injection with ES cells. However, in the mature GV cytoplasm, chromosomes were distributed throughout the cytoplasm and a much bigger spindle was formed. Pseudopronucleus formation was observed in pro-MI and MII cytoplasm after activation treatment. Although no pronucleus formation was found in GV cytoplasm, chromosomes segregated into two groups in response to activation. Only 8.1% of reconstructed embryos with pro-MI cytoplasm developed to the morula stage after culture in CZB medium. In contrast, 53.5% of embryos reconstructed with MII cytoplasm developed to the morula/blastocyst stage, and 5.3% of transferred embryos developed to term. These results indicate that GV material is essential for nucleus remodeling after nuclear transfer.     

In vitro development of reconstructed bovine embryos and fate of donor mitochondria following nuclear injection of cumulus cells

In this study we examined the developmental potential of reconstructed embryos and the fate of donor mitochondria during preimplantation development after nuclear transfer in cattle. Isolated cumulus cells were used as donor cells in nuclear transfer. Cumulus cells labelled with MitoTracker Green FM fluorochrome were injected into enucleated bovine MII oocytes and cultured in vitro. MitoTracker labelling on donor cells did not have a detrimental effect on blastocyst formation following nuclear transfer. Cleavage rate was about 69% (56/81) and blastocyst formation rate was 6.2% (5/81) at 7 days after nuclear transfer. The labelled mitochondria dispersed to the cytoplasm and became distributed between blastomeres and could be identified up to the 8- to 15-cell stage. Small patches of mitochondria were detected in some 8- to 15-cell stage embryos (5/20). However, donor mitochondria were not detected in embryos at the 16-cell stage and subsequent developmental stages. In the control group, mitochondria could be identified in arrested 1-cell embryos up to 7 days after nuclear transfer. These results suggest that disappearance of the labelled donor mitochondria in nuclear transfer bovine embryos is not due to fading of the fluorochrome marker, but is rather an as yet undefined cytoplasmic event.     

Development of embryos reconstructed by interspecies nuclear transfer of adult fibroblasts between buffalo (Bubalus bubalis) and cattle (Bos indicus)

The objective of this study was to explore the feasibility of employing adult fibroblasts as donor cells in interspecies nuclear transfer (NT) between buffaloes and cattle. Buffalo and bovine oocytes matured in vitro for 22 h were enucleated by micromanipulation using the Spindle View system. An ear fibroblast, pretreated with 0.1 microg/mL aphidicolin for 24 h, followed by culture for 2-9 days in Dulbecco's Modified Eagle's Media+0.5% fetal bovine serum, was introduced into the cytoplast by microinjection. Reconstructed oocytes were activated by exposure to 5 microM ionomycin for 5 min and 2 mM 6-dimethylaminopurine for 3 h. When buffalo adult fibroblasts were used as donor cells, there were no differences (P < 0.75) in the cleavage rate (66.2% versus 64.0%) between bovine and buffalo recipient oocytes, but more embryos derived from bovine cytoplasts developed to blastocysts than from buffalo cytoplasts (13.3% versus 3.0%, P < 0.05). When bovine adult fibroblasts were used as donor nuclei, both cleavage rate (45.3%) and blastocyst yield (4.5%) of NT embryos derived from buffalo cytoplasts were lower than those of NT embryos derived from bovine cytoplasts (65.5 and 11.9%, P < 0.05). The proportion of parthenogenetic buffalo (29.1%) or bovine (35.6%) oocytes developing to blastocysts was higher than those of NT embryos (P < 0.01). Interspecies NT embryos were derived from the donor cells and 55.0-61.9% of them possessed a normal diploid karyotype. In conclusion, embryos reconstructed by interspecies NT of adult fibroblasts between buffaloes and cattle developed to blastocysts, but bovine cytoplasts may direct embryonic development more effectively than buffalo cytoplasts, regardless of donor cell species.     

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.     

Blastocyst development after intergeneric nuclear transfer of mountain bongo antelope somatic cells into bovine oocytes

Intergeneric embryos were constructed by nuclear transfer using Mountain Bongo antelope somatic cells fused with enucleated bovine oocytes and their subsequent development in vitro was investigated. After two to six passages, starved or non-starved skin fibroblast cells were used as donor nuclei. In vitro matured bovine oocytes were enucleated by squeezing the first polar body and surrounding cytoplasm through a slit in the zona pellucida. After injection of a somatic cell into the perivitelline space, couplets were fused electrically and activated chemically, then subjected to different embryo culture treatments. Serum starvation had no effect on the frequency of cleavage to two cells or on development to the blastocyst stage in either sequential hamster embryo culture medium (HECM)-6/TCM-199 + serum or HECM-9/TC-199 + serum, or modified synthetic oviduct fluid (mSOF) culture medium. When couplets from non-starved donor nuclei were cultured, the frequency of cleavage (66 +/- 8% vs. 44 +/- 5%), development to >/=9 cells (46 +/- 6% vs. 24 +/- 4%), and formation of blastocysts (24 +/- 5% vs. 11 +/- 2%) were all significantly higher (p < 0.05) in the HECM-6 medium than in mSOF medium. In conclusion, bovine oocytes can support blastocyst development after intergeneric fusion with bongo fibroblasts. This technique could potentially be used as an alternative to using scarce bongo oocytes in attempts to propagate these endangered animals.     

In vitro and in vivo survival of frozen-thawed bovine oocytes after IVF,nuclear transfer,and parthenogenetic activation

Cryopreservation of bovine oocytes would be beneficial both for nuclear transfer and for preservation efforts. The overall objective of this study was to evaluate the viability as well as the cryodamage to the nucleus vs. cytoplasm of bovine oocytes following freezing-thawing of oocytes at immature (GV) and matured (MII) stages using in vitro fertilization (IVF), parthenogenetic activation, or nuclear transfer assays. Oocytes were collected from slaughterhouse ovaries. Oocytes at the GV, MII, or MII but enucleated (MIIe) stages were cryopreserved in 5% (v/v) ethylene glycol; 6% (v/v) 1,2-propanediol; and 0.1-M sucrose in PBS supplemented with 20% (v/v) fetal bovine serum. Frozen-thawed oocytes were subjected to IVF, parthenogenetic activation, or nuclear transfer assays. Significantly fewer GV oocytes survived (i.e., remained morphologically intact during freezing-thawing) than did MII oocytes (47% vs. 84%). Subsequent development of the surviving frozen-thawed GV and MII oocytes was not different (58% and 60% cleavage development; 7% and 12% blastocyst development at Day 9, respectively, P > 0.05). Parthenogenetic activation of frozen-thawed oocytes resulted in significantly lower rates of blastocyst development for the GV than the MII oocyte groups (1% vs. 14%). Nuclear transfer with cytoplasts derived from frozen-thawed GV, MII, MIIe, and fresh-MII control oocytes resulted in 5%, 16%, 14%, and 17% blastocyst development, respectively. However, results of preliminary embryo transfer trials showed that fewer pregnancies were produced from cloned embryos derived from frozen oocytes or cytoplasts (9%, n = 11 embryos) than from fresh ones (19%, n = 21 embryos). Transfer of embryos derived by IVF from cryopreserved GV and MII oocytes also resulted in term development of calves. Our results showed that both GV and MII oocytes could survive freezing and were capable of developing into offspring following IVF or nuclear transfer. However, blastocyst development of frozen-thawed oocytes remains poorer than that of fresh oocytes, and our nuclear transfer assay suggests that this poorer development was likely caused by cryodamage to the oocyte cytoplasm as well as to the nucleus. Mol. Reprod. Dev. 51:281–286, 1998. © 1998 Wiley-Liss, Inc.     

Activated bovine cytoplasts prepared by demecolcine-induced enucleation support development of nuclear transfer embryos in vitro

Demecolcine-induced enucleation (IE) of mouse oocytes has been shown to improve development to term of cloned mice. In this study, we characterized the kinetics and morphological progression of bovine oocytes subjected to IE, and evaluated their ability to support embryo development to the blastocyst stage after nuclear transfer (NT). In vitro matured bovine oocytes were parthenogenetically activated and subsequently exposed to demecolcine at various times post-activation. Onset and duration of demecolcine treatment significantly altered activation and IE frequencies, which varied from 7.1% to 100% and 33.3% to 91.7%, respectively, at 5 hr post-activation. A significant decrease in IE frequencies was observed at 17 hr post-activation (3.4%-46.1%), possibly due to reincorporation of chromosomes into the oocyte after incomplete second polar body (PB) extrusion. Oocytes were reconstructed by NT before (treatment 1) or after (treatment 2) activation and demecolcine treatment, and cultured in vitro. Cleavage (48.1%-54.2%) and blastocyst rates (15.7%-19%) were equivalent for the two treatments, as well as the total cell number in NT blastocysts. Furthermore, most of the blastocysts were completely diploid (treatment 2) or heteroploid but with a majority of diploid nuclei (treatment 1). Our results demonstrate that the IE method can be successfully used to produce enucleated bovine cytoplasts that are competent to support development to the blastocyst stage after NT. This technically simple approach may provide a more efficient method to enhance the success rate of NT procedures. Further studies are needed to improve the in vitro development efficiency and to expand our understanding of the mechanism(s) involved in demecolcine-induced enucleation.     

Nuclear and cytoskeletal dynamics during oocyte maturation and development of somatic cell cloned pig embryos injected with membrane disintegrated donor cells

The objectives of this study were to characterize the nuclear and cytoskeletal changes of pig oocytes during in vitro maturation (IVM) and the development of the reconstructed embryos after injection with membrane intact or disintegrated donor cells. Cumulus-oocyte complexes (COCs) were collected from abattoir ovaries by follicle (2-8mm) aspiration. In Experiment 1, COCs were cultured in NCSU-23 medium for 0, 11, 22, 33, and 44 h. Oocytes were fixed at different time points for nuclear and cytoskeletal labeling. Forty-three percent and 75% oocytes progressed to MII stage at 33 and 44 h after IVM culture, respectively. Dynamic shift of spindle and cytoplasmic microtubules was evident. In Experiment 2, matured oocytes were injected with either the whole cumulus cell with or without intact cell membranes after enucleation. The reconstructed oocytes were fixed at 0, 2, or 4 h after cell injection for nuclear and cytoskeletal evaluation. When an intact cumulus cell was injected, the injected cell remained intact within 4h after injection. When a cell with disintegrated membrane was injected, 59-63% (n=146) of the injected cell underwent premature chromosome condensation (PCC). In Experiment 3, the reconstructed pig oocytes received membrane-disintegrated cumulus cells or fetal fibroblasts were cultured in PZM medium. The blastocyst rate of the fibroblast-injected embryos was 10%, which was lower than the non-cloned parthenotes (33%, P<0.05) but higher than the cumulus cell-injected embryos (2.7%). These results suggest that pig oocytes are subjected to nuclear and cytoskeletal reorganization during maturation. Pig oocytes injected with membrane-disintegrated fibroblast cells support better blastocyst development of the cloned embryos.     

Bovine nuclear transfer using fresh cumulus cell nuclei and in vivo- or in vitro-matured cytoplasts

We examined the effects of the source of recipient oocytes and timing of fusion and activation on the development competence of bovine nuclear transferred (NT) embryos derived from fresh cumulus cells isolated immediately after collection by ovum pickup (OPU). As recipient cytoplasts, we used in vivo-matured oocytes collected from hormone-treated heifers by OPU, or in vitro-matured oocytes from slaughterhouse-derived ovaries. NT embryos were chemically activated immediately (simultaneous fusion and activation, FA) or 2 h (delayed activation, DA) after fusion. When in vitro-matured oocytes were used as recipient cytoplasts, the development rate to the blastocyst stage of NT embryos produced by the DA method (23%) tended to be higher than those by the FA method (15%), but the difference was not significant. NT embryos derived from in vivo-matured cytoplasts have a high blastocyst yield (46%). Pregnancy rate at day 35 did not differ with the timing of fusion and activation (FA vs. DA; 50% vs. 44%) or oocyte source (in vivo- vs. in vitro-matured; 50% vs. 44%). Subsequently, the high fetal losses (88% of pregnancies) were observed with in vitro-matured cytoplasts, whereas no abortions were observed in NT fetuses from in vivo-matured cytoplasts. A total of three embryos derived from fresh cumulus cells developed to term. However, all three cloned calves were stillborn. These results indicate that improvement of development competence after NT is possible by using in vivo-matured oocytes as recipient cytoplasts in bovine NT.     

Noninvasive chemical enucleation of mouse oocytes

A noninvasive method of enucleating mouse oocytes has been developed and evaluated. Strong chromosome to chromosome binding was induced by culturing early metaphase I oocytes in etoposide supplemented medium. Subsequent expulsion of the entire chromosome complex during polar body extrusion was facilitated by exposing the etoposide treated oocytes to a combination of cycloheximide and etoposide during anaphase and telophase. This simple two-step chemical enucleation procedure yields fully enucleated mouse oocytes in 96% of cases. Chemically enucleated oocytes do not contain maturation promoting factor (MPF) at the end of etoposide-cycloheximide enucleation. MPF levels are, however, restored during subsequent incubation in drug-free medium and, after 15 h of post-enucleation culture, the cytoplasts regain their full capacity for parthenogenetic activation and nuclear remodelling. We believe that this novel enucleation technique will greatly facilitate the research in nuclear transplantation. © 1993 Wiley-Liss, Inc.