Effect of ooplast activation on the development of oocytes following nucleus transfer in cattle

Improvement of the developmental ability of nuclear transfer embryos by using blastomeres from in vitro fertilized embryos selected according to the early developmental stage and cell division status as donor cells in cattle

This study was conducted to improve the developmental ability of nuclear transfer (NT) embryos by using blastomeres from in vitro fertilized (IVF) embryos with high quality as donor cells. The IVF embryos selected at the 2-cell stage at 24-h postinsemination (hpi) and again at the ≥8-cell stage at 48 hpi (Selected-IVF-embryos) showed the highest blastocyst formation rate among embryos. When blastomeres from the Selected-IVF-embryos (Selected-NT group) or Nonselected-IVF-embryos (Non-selected-NT group) were used as donor cells for NT, the blastocyst formation rate in the Selected-NT group (25.6%) was significantly higher than that in the Non-selected-NT group (13.5%). When blastomeres from the Selected-IVF-embryos at 108 (contained many cells before cell division) and 126 hpi (contained many cells immediately after cell division) were used as donor cells for NT (108- and 126-NT groups, respectively), the 126-NT group showed a significantly higher blastocyst formation rate (32.1%) than the 108-NT group (16.8%). Embryo transfer of blastocysts in the 126-NT group showed that 11 of 23 recipients became pregnant; nine calves were obtained. For the NT embryos reconstructed using in vivo derived embryos, 9 of 20 recipients became pregnant; seven calves were obtained. These results indicate that the blastocyst formation rate of NT embryos can be improved by using blastomeres from IVF embryos selected at the early developmental stage, especially immediately after cell division, and that the resultant NT embryos have a high developmental ability to progress to term that is comparable to NT embryos reconstructed using in vivo derived embryos.

Nuclear and nucleolar reprogramming during the first cell cycle in bovine nuclear transfer embryos

The immediate events of genomic reprogramming at somatic cell nuclear transfer (SCNT) are to high degree unknown. This study was designed to evaluate the nuclear and nucleolar changes during the first cell cycle. Bovine SCNT embryos were produced from starved bovine fibroblasts and fixed at 0.5, 1, 2, 3, 4, 8, 12, and 16 h postactivation (hpa). Parthenogenetic (PA) embryos were used as control. The SCNT and PA embryos were processed for lacmoid staining, autoradiography, transmission electron microscopy (TEM), and immunofluorescence localization of: upstream binding factor (UBF) and fibrillarin at 4 and 12 hpa. Likewise, starved and nonstarved fibroblasts were processed for autoradiography and TEM. The fibroblasts displayed strong transcriptional activity and active fibrillogranular nucleoli. None of the reconstructed embryos, however, displayed transcriptional activity. In conclusion, somatic cell nuclei introduced into enucleated oocytes displayed chromatin condensation, partial nuclear envelope breakdown, nucleolar desegregation and transcriptional quiescence already at 0.5 hpa. Somatic cell cytoplasm remained temporally attached to introduced nucleus and nucleolus was partially restored indicating somatic influence in the early SCNT phases. At 1-3 hpa, chromatin gradually decondensed toward the nucleus periphery and nuclear envelope reformed. From 4 hpa, the somatic cell nucleus gained a PN-like appearance and displayed NPBs suggesting ooplasmic control of development.

Developmental potential of bovine nuclear transfer embryos and postnatal survival rate of cloned calves produced by two different timings of fusion and activation

We compared developmental potential of somatic cell nuclear transfer (NT) embryos and postnatal survivability of cloned calves produced by two different fusion and activation protocols. As donor cells for NT, bovine cumulus cell-derived cultured cells of passage 5 were used following culture in serum-starved medium for 5-7 days. Enucleated oocytes were fused with donor cells at 21 or 24 hr post maturation. NT embryos fused at 21 hr were activated chemically 3 hr after fusion (DA group) and embryos fused at 24 hr were activated chemically immediately after fusion (FA group). Chemical activation was accomplished by calcium ionophore for 5 min and cytochalasin D + cycloheximide for 1 hr then cycloheximide alone for 4 hr. After in vitro culture in IVD101 medium for 7 days, embryo transfer was performed. Fusion rates were 86 and 84% in the DA and FA groups, respectively. Developmental rate to the blastocyst stage of NT embryos in the DA group was higher than in the FA group (42% vs. 28%). Pregnancy rate did not differ significantly between the DA and FA groups (11/13 and 5/7 at day 35), and 13 cloned calves (including 1 set of twins from a single embryo transfer) were born. High rates of postnatal mortality were observed in both groups. These results suggest that the DA method improves in vitro developmental potential of NT embryos, but the timing of fusion and chemical activation does not affect the pregnancy rate and the survivability of cloned calves.

Development of bovine oocytes reconstructed with a nucleus from growing stage oocytes after fertilization in vitro

The developmental capacity of reconstructed bovine oocytes that contained nuclei from growing stage oocytes, 70-119 microm in diameter, was assessed after fertilization in vitro. Nuclei from growing stage oocytes of adult ovaries were transferred to enucleated, fully grown germinal vesicle (GV) stage oocytes. After culture in vitro, the reconstructed oocytes matured, forming the first polar body and MII plate. To supply the ability to form pronuclei, the resultant MII plate was transferred to enucleated MII oocytes, which were obtained by in vitro culture of cumulus-oocyte complexes. After fertilization in vitro, 11-15% of the reconstructed oocytes developed to morulae and blastocysts. To assess the ability to develop to term, a total of 27 late morulae and blastocysts were transferred to 19 recipient cows. Of the three cows that subsequently became pregnant, one recipient, who received two embryos derived from reconstructed oocytes with a nucleus from oocytes 100 to 109 microm in diameter, continued the pregnancy to Day 278 of gestation. This pregnancy, however, was unexpectedly a triplet pregnancy that included a set of identical twins and resulted in the premature birth of the calves, followed by death from lack of post-parturient treatment. These results show that bovine oocyte genomes are capable of supporting term development before the oocytes grow to their full size, which suggests that growing stage oocytes can be directly used as a source of maternal genomes.

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.

Development of porcine embryos reconstituted with somatic cells and enucleated metaphase I and II oocytes matured in a protein-free medium

BACKGROUND

Many cloned animals have been created by transfer of differentiated cells at G0/G1 or M phase of the cell cycle into enucleated M II oocytes having high maturation/meiosis/mitosis-promoting factor activity. Because maturation/meiosis/mitosis-promoting factor activity during oocyte maturation is maximal at both M I and M II, M I oocytes may reprogram differentiated cell nuclei as well. The present study was conducted to examine the developmental ability in vitro of porcine embryos reconstructed by transferring somatic cells (ear fibroblasts) into enucleated M I or M II oocytes.

RESULTS

Analysis of the cell cycle stages revealed that 91.2 +/- 0.2% of confluent cells were at the G0/G1 phase and 54.1 +/- 4.4% of nocodazole-treated cells were at the G2/M phase, respectively. At 6 h after activation, nuclear swelling was observed in 50.0-88.9% and 34.4-39.5% of embryos reconstituted with confluent cells and nocodazole-treated cells regardless of the recipient oocytes, respectively. The incidence of both a swollen nucleus and polar body was low (6.3-10.5%) for all nocodazole-treated donor cell regardless of the recipient oocyte. When embryos reconstituted with confluent cells and M I oocytes were cultured, 2 (1.5%) blastocysts were obtained and this was significantly (P < 0.05) lower than that (7.6%) of embryos produced by transferring confluent cells into M II oocytes. No reconstructed embryos developed to the blastocyst stage when nocodazole-treated cells were used as donors.

CONCLUSIONS

Porcine M I oocytes have a potential to develop into blastocysts after nuclear transfer of somatic cells.

A separate procedure of fusion and activation in an ear fibroblast nuclear transfer program improves preimplantation development of bovine reconstituted oocytes

This study was conducted to examine whether preimplantation development of bovine ("HanWoo," Bos Taurus corcanae) oocytes reconstituted with ear fibroblasts could be improved by a modified procedure of fusion and activation. In Experiment 1, enucleated oocytes were reconstituted with ear fibroblast by a combined procedure of electric fusion and activation at either 24 or 28 hours after IVM. The 28 hours reconstitution yielded more blastocysts (4% vs. 21%, P = 0.0025) and higher ratio of blastocysts per 2-cell embryos (0.05 vs. 0.25, P = 0.003) than the 24 hours. In Experiment 2, enucleated oocytes were reconstituted by one of the three fusion and activation protocols; 1) a combined procedure of electric fusion and activation at 28 hours after IVM, 2) a combined procedure of electric fusion and chemical activation at 28 hours, and 3) a separate procedure of electric fusion at 24 hours and chemical activation at 28 hours. When compared two combined procedures, chemical activation with 5 microM ionomycin for 4 minutes did not promote embryo development and significantly reduced the fusion rate (42% vs. 53%, P = 0.0395). However, significant (P < 0.0113) increases in the development to 2-cell (90% vs. 70 to 74%) and blastocyst (47% vs. 7 to 13%) stages and in the ratio of blastocysts per 2-cell embryos (0.52 vs. 0.11 to 0.18) were obtained by a separate procedure of electric fusion and chemical activation than by the combined procedures. This separate protocol did not reduce the fusion rate compared with the combined procedures (58%). In conclusion, improved development of oocytes reconstituted with ear fibroblasts was achieved by undergoing a separate procedure of electric fusion and chemical activation 4 hours apart.

Activity of Maturation Promoting Factor (MPF) and Mitogen-Activated Protein Kinase (MAPK) after Parthenogenetic Activation of Ovine Oocytes

The maturation promoting factor (MPF) and mitogen-activated protein kinase (MAPK) are the key regulators of both meiotic and mitotic cell cycles. Knowledge of the dynamics of these two kinases during the transition from meiosis to mitosis would be of great importance for cloning by nuclear transfer. In this study, experiments were designed to assay the changes of MPF and MAP kinase activity of in vitro matured ovine oocytes after chemical activation and culture in 0 mM or 2 mM 6-dimethylaminopurine (6-DMAP) for 12 h. Moreover, to determine the biological significance of the fluctuations of MPF, activated oocytes were fused with GV-staged partners. The biochemical results showed that the high MPF activity of MII oocytes fell to basal level precipitously within the first hour after activation, started to increase at 6-8 h, rising to 80 +/- 4% of MII after 12 h. MAPK activity decreased to a low level 4 h after activation, increased between 6-12 h, but remained below 30 +/- 3.6% of MII values. The incubation with 6-DMAP had no effect on the kinetics of MPF and MAP kinase activity. Fusion of MII oocytes to GV partners induced rapid breakdown of the GV, whereas no breakdown occurred when GV were fused with eggs in the first hours post activation. Interestingly, the high biochemical levels of MPF activity at 8-12 h after activation were not able to induce GVBD in fusion partners.

Transmitochondrial differences and varying levels of heteroplasmy in nuclear transfer cloned cattle

To assess the extent of cytoplasmic genetic variability in cloned cattle produced by nuclear transplantation procedures, we investigated 29 individuals of seven male cattle clones (sizes 2-6) from two different commercial sources. Restriction enzyme and direct sequence analysis of mitochondrial DNA (mtDNA) detected a total of 12 different haplotypes. Transmitochondrial individuals (i.e., animals which share identical nuclei but have different mitochondrial DNA) were detected in all but one of the clones, demonstrating that mtDNA variation among cloned cattle is a very common phenomenon which prevents true genetic identity. The analyses also showed that the cytoplasmic genetic status of some investigated individuals and clones is further complicated by heteroplasmy (more than one mtDNA type in an individual). The relative proportions of different mtDNA-types in two animals with mild heteroplasmy were estimated at 2:98% and 4:96% in DNA samples derived from blood. This is in agreement with values expected from karyoplast-cytoplast volume ratios. In contrast, the mtDNA haplotype proportions observed in six other heteroplasmic animals of two different clones ranged from 21:79% to 57:43%, reflecting a marked increase in donor blastomere mtDNA contributions. These results suggest that mtDNA type of donor embryos and recipient oocytes used in nuclear transfer cattle cloning should be controlled to obtain true clones with identical nuclear and cytoplasmic genomes.

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.

Preparation of young preactivated oocytes with high enucleation efficiency for bovine nuclear transfer

To improve the enucleation rate in newly matured bovine oocytes, we investigated the position of cytoplasmic chromatin in relation to the polar body and the consequent enucleation efficiency before and after sequential activation with calcium ionophore A23187 and cycloheximide. Oocytes aspirated from the follicles of slaughterhouse-collected ovaries were cultured for 18 to 20 h. With Hoechst staining, only 40.7% of the chromatin material was found adjacent to the first polar body in metaphase II oocytes, while 100% was located adjacent to the second polar body in oocytes after the activation. Enucleation trials after activation showed a higher enucleation rate (91.5%) than that before activation (59.9%). The following experiment determined the effect of using both kinds of cytoplast on the in vitro development of nuclear transfer embryos. Blastomeres of the 32-cell-stage in vitro-produced embryos were transferred, fused to the activated cytoplasts and cultured in vitro. No significant difference was detected in fusion, cleavage or development to blastocysts obtained 7 d (174 h) post fusion. In conclusion, this study showed that young in vitro-matured bovine oocytes sequentially activated with calcium ionophore and cycloheximide have cytoplasmic chromatin material adjacent to the second polar body, leading to a high enucleation rate.

Telophase enucleation: an improved method to prepare recipient cytoplasts for use in bovine nuclear transfer

The enucleation of oocytes to be used as host cytoplasts for embryo reconstruction by nuclear transfer is an important limiting step when cloning mammals. We propose an enucleation technique based on the removal of chromatin after oocyte activation, at the telophase stage, by aspirating the second polar body and surrounding cytoplasm. In a preliminary experiment to determine an optimal activation protocol, oocytes were matured for 26 and 30 hr and exposed for 5 min to 7% ethanol and/or for 3 hr at either 25 or 4 degrees C. Relative to most activation treatments tested, oocytes matured for 30 hr and exposed to ethanol alone showed highest activation rates, as determined by low levels of H1 kinase activity within 90 min from exposure and high pronuclear formation (82%) after 12 hr of culture. No synergistic effect on activation rates was observed when oocytes also were exposed to reduced temperature after ethanol treatment. Microsurgical removal of the telophase-stage chromatin in a small volume of cytoplasm adjacent to the second polar body was significantly more effective in enucleating than aspiration of a larger cytoplasm volume surrounding the first polar body of metaphase-arrested oocytes (98% versus 59%; P < 0.01). Moreover, compared with a nuclear transfer protocol based on enucleation of metaphase-arrested oocytes followed by aging and cooling, more (38% versus 16%; P < 0.001) and better-quality blastocytes (126 versus 84 nuclei per blastocyst; P < 0.02) were obtained from embryos reconstructed using the telophase procedure. Higher development potential of embryos reconstructed by the telophase procedure may be attributed to (1) the selection of oocytes that activate and respond by extruding the second polar body, (2) avoiding the use of DNA dyes and ultraviolet irradiation, and (3) the limited removal of cytoplasm during enucleation. The ease with which telophase enucleation can be performed is likely to render this technique widely useful for research and practice on mammalian cloning.

Influence of combined activation treatments on the success of bovine nuclear transfer using young or aged oocytes

This study was determined if the combined activation of young or aged oocytes influence their development. The 16-cell stage in vitro maturation/fertilization embryos were exposed to 10 microL nocodazole for 18-20 h, blastomeres that divided within 3 h after the release from nocodazole were used as synchronized donor blastomeres. Metaphase II oocytes were enucleated at 20-22 h post onset of maturation. Enucleated oocytes were divided into 2 groups: oocytes activated at 24 h (young) and oocytes activated at 38 h (aged). In both groups (young and aged), one group of oocytes was activated in 7% ethanol alone for 5 min (alone) and the other group (combination) was activated in ethanol and subsequently incubated in 5 micrograms/ml cycloheximide in TCM199 for 6 h (combination). Electrofusion was carried out at 30 h (young) and 44 h (aged). The nuclear morphology of the blastomere-oocyte complexes at 1 h post-fusion and their development to the blastocyst stage after 6 days of culture in modified synthetic oviduct fluid were examined. Interphase and swollen nuclei were observed at 1 h post-fusion following nuclear transfer to the cytoplasm from young oocytes of combined activation and aged oocytes of combined and ethanol alone activation. When young oocytes were treated with the combined activation method, the reconstituted embryos had a significantly higher developmental rate to the blastocyst stage than the aged oocyte groups (P < 0.05). We conclude that the combined activation of young oocytes leads to a more efficient development of bovine nuclear transfer embryos.

Nuclear transfer of porcine embryos using cryopreserved delipated blastomeres as donor nuclei

Nuclear transfer protocol for the pig using cryopreserved delipated four- to eight-cell and morula stage embryos as nucleus donors was developed. Donor embryos, which had been delipated by micromanipulation following centrifugation for polarizing cytoplasmic lipid droplets, were cryopreserved with 1.5 M 1,2-propanediol and 0.1 M sucrose. Recipient cytoplasts were prepared from ovulated oocytes. Activation of oocytes could be induced more efficiently when electric stimulation was given 53 hr after the hCG injection or later (66-83%), compared with 52 hr or earlier (11-16%, P < 0.05), suggesting that aging after ovulation may be required for in vivo matured porcine oocytes to be activated by electric stimuli. Membrane fusion rates between donor blastomeres and enucleated oocytes were 88% (127/144) and 97% (56/58, P > 0.05) for the four- to eight-cell and morula stage embryos, respectively. In vitro developmental rates to the two-cell (53/100 vs. 35/65), four-cell (34/100 vs. 26/65), and morula stage (17/100 vs. 18/65) were the same between the nuclear transfer embryos with four- to eight-cell and morula nuclei. However, more embryos reconstituted with morula nuclei developed to blastocysts (15% vs. 6%, P < 0.05). These data demonstrated that blastomeres of cryopreserved, delipated porcine embryos can be used as donor nuclei for nuclear transfer. Frozen-thawed, delipated blastomeres can be efficiently isolated and fused, and therefore provide a useful source of donor nuclei.

Nuclear transfer in sheep embryos: the effect of cell-cycle coordination between nucleus and cytoplasm and the use of in vitro matured oocytes

The developmental ability of nuclear transplant sheep embryos derived from in vitro matured oocytes was studied by controlling cell-cycle coordination of donor embryonic nuclei and recipient cytoplasts. Oocytes were recovered from nonatretic antral follicles of adult sheep ovaries and cocultured with follicle shells in M199-based medium supplemented with gonadotrophins in a nonstatic system. Effective activation if IVM oocytes was obtained by applying two pulses of 1.0 kv/cm 22 min apart in inositol-based electroporation medium to oocytes matured in vitro for 27 hr. Synthesis of DNA (S-phase) was assessed by BrdU incorporation and was found to initiate around 5 hpa (hours postactivation) and to persist until 18 hpa. Mitotic blastomeres were induced by treating embryos with 6.6 microM nocodazole for 14-17 hr. Three types of transfers were compared directly: "S-->S," early embryonic nuclei (mostly in S-phase) were transferred to presumptive S-phase cytoplasts; "M-->MII," nocodazole-treated embryonic nuclei (most in M-phase) were transferred to MII-phase cytoplasts; and control (S-->MII), conventional nuclear transfer of fusion and activation simultaneously. The results showed that fusion and recovery rates did not differ among the three groups. However, after 6 days of in vivo culture, the morula and blastocyst formation rate was significantly higher for the M-->MII combination than for the control (28.3% vs. 8.1%, P < 0.05), while no significant differences in developmental rate were observed between S-->S and M-->MII, and between S-->S and control, though developmental rate was also increased for S-->S compared to control (20.9% vs. 8.1%, P > 0.05). Transfer of blastocysts derived from M-->MII or S-->S nuclear cytoplasmic reconstitution to synchronized recipient ewes resulted in the birth of lambs. These data suggest that in vitro matured oocytes can support full-term development of nuclear transplant sheep embryos when the cell cycle of nucleus and cytoplasm is coordinated, and that M-->MII nuclear transfer might be an efficient and simple way to improve the developmental competence of the reconstituted embryos.

Influence of recipient cytoplasm cell stage on transcription in bovine nucleus transfer embryos

Nucleus transfer for the production of multiple embryos derived from a donor embryo relies upon the reprogramming of the donor nucleus so that it behaves similar to a zygotic nucleus. One indication of nucleus reprogramming is the RNA synthetic activity. In normal bovine embryogenesis, the embryo relies upon maternally derived RNA transcripts up to the 8-cell stage, at which time it begins to transcribe its own RNA. In this experiment, RNA synthesis was detected in nucleus transfer embryos (NTE) and control embryos by pulsing with 3H-uridine, fixation, and autoradiography on semithin sections. NTE were produced using either a MII phase (nonactivated) cytoplasts at 32 hr of maturation or S-phase (activated) cytoplasts activated with calcium ionophore A23187 and cycloheximide treatment approximately 8 hr prior to fusion with a blastomere from an in-vitro-produced morula stage embryo at 32 hr of maturation. Control in-vitro-produced embryos were 3H-uridine-labelled and fixed at the 2-, 4-, early 8-, and late 8-cell stages. NTE were similarly prepared at 1, 3, and 20 hr postfusion and at the 2-, 4-, and 8-cell stages. In the control embryos, RNA synthesis was absent in the 2-, 4-, and early 8-cell stages, whereas in all late 8-cell stages, it was present. In NTE from nonactivated (MII phase) cytoplasts, there was a sharp decline in RNA synthesis at 1 hr and 3 hr after fusion and a total absence by 20 hr after fusion. In contrast, NTE from activated (S phase) cytoplasts exhibited continued high levels of RNA synthesis at 1 hr and moderate levels at 3 hr after fusion, although it had ceased by 20 hr after fusion. In all NTE (activated and nonactivated cytoplasts), there was no RNA synthesis seen at the 2-cell stage. However, at the 4-cell stage, weak RNA synthesis was seen in all NTE from activated cytoplasts, whereas none was observed in those from MII nonactivated cytoplasts. At the 8-cell stage, nearly all NTE from S-phase cytoplasts showed weak to moderate levels of RNA synthesis. We conclude that the nucleus reprogramming differs between NTE reconstructed from activated and nonactivated cytoplast with the former undergoing a slower cessation of RNA synthesis after fusion and earlier resumption of RNA synthesis, occurring as early as the 4-cell stage.

Production of identical sextuplet mice by transferring metaphase nuclei from four-cell embryos

Mouse clones were produced by serial nuclear transfer commencing with the transfer of four-cell nuclei at metaphase into unfertilized ooplasts. The donor four-cell-stage nuclei were synchronized in metaphase with nocodazole. The oocytes receiving a four-cell nucleus at metaphase formed two nuclei after artificial activation and inhibition of cytokinesis with cytochalasin B. To obtain embryos with diploid sets of chromosomes, nuclei from each reconstructed embryo were transferred individually into separate enucleated fertilized one-cell embryos, thus doubling the number of identical embryos. This procedure produced a high frequency of development of reconstructed embryos to the blastocyst stage. Of 11 sets of identical embryos produced by serial nuclear transplantation, 83% developed into blastocysts, including three sets of identical septuplet blastocysts. After transfer to recipient mice, a total of 25 (57%) live young were obtained, which included one set of identical sextuplet and two sets of identical quadruplet mice.

Electrofusion parameters for nuclear transfer predicted using isofusion contours produced with bovine embryonic cells

Electrofusion is a valuable technique for the nuclear transfer procedure. An enucleated oocyte is electrofused with a blastomere to create a nuclear transfer embryo. The present study constructed isofusion contours after the electrofusion of identical coupled cells that characterized all the bovine embryonic cell types used in nuclear transfer. The intersection of isofusion contours for enucleated oocytes and blastomeres provided the parameters for electrofusion during nuclear transfer. Blastomeres isolated from in vitro produced embryos 3-6 days after (in vitro fertilization) were electrofused with oocytes enucleated by centrifugation (85, 87, 89, and 73% electrofusion, respectively). The cleavage (46, 40, 37, and 28%, respectively) of the nuclear transfer embryos produced a trend that decreased as the age of the blastomeres increased. The isofusion contours provided information about the interaction between different cell types in an electric field, and gave precise electrofusion parameters for a range of bovine embryonic cell types used in nuclear transfer.

Effect of donor embryo cell number and cell size on the efficiency of bovine embryo cloning

To establish reliable criteria for the evaluation of nuclear donor embryos, we studied the effect of cell number and cell size of in vitro produced day 6 donor morulae on the rate of blastocyst formation following nuclear transfer to in vitro matured oocytes. In experiment 1, donor embryos were divided into three groups with low (25-34), intermediate (40-55), and high (60-81) blastomere numbers. Transfer of nuclei from day 6 morulae with intermediate and high cell numbers resulted in a significantly higher blastocyst rate (31% and 32%, respectively) than use of nuclei from day 6 morulae with low cell numbers (17%) or nuclei from day 7 morulae with 50-83 blastomeres (19%). This suggests that blastomeres from the developmentally advanced day 6 morulae are more viable than blastomeres from retarded embryos. In experiment 2, we evaluated the effect of blastomere size in day 6 donor morulae with intermediate (40-55) or high (60-81) cell numbers on the efficiency of nuclear transfer. In both classes of embryos, small blastomeres were better nuclear donors than large blastomeres. The rates of development to the blastocyst stage were 28% versus 15% (40-55 cells) and 41% versus 25% (60-81 cells), suggesting that small blastomeres include a higher proportion of totipotent cells than the polarized large blastomeres. Our results demonstrate that blastomere number and size markedly affect the efficiency of nuclear transfer and therefore are useful criteria for evaluating nuclear donor embryos. These parameters are easy to determine and may therefore be helpful to improve the efficiency of cattle cloning.