Birth of African Wildcat cloned kittens born from domestic cats

In the present study, we used the African Wildcat (Felis silvestris lybica) as a somatic cell donor to evaluate the in vivo developmental competence, after transfer into domestic cat recipients, of cloned embryos produced by the fusion of African Wildcat (AWC) fibroblast cell nuclei with domestic cat cytoplasts. Cloned embryos were produced by fusion of a single AWC somatic cell to in vivo or in vitro enucleated domestic cat cytoplasts. When the two sources of oocytes were compared, fusion rate was higher using in vivo-matured oocytes as recipient cytoplasts, but cleavage rate was higher after reconstruction of in vitro-matured oocytes. To determine the number of reconstructed embryos required per domestic cat recipient to consistently establish pregnancies, AWC cloned embryos were transferred within two groups: recipients (n = 24) receiving < or =25 embryos and recipients (n = 26) receiving > or =30 embryos. Twelve recipients (46.2%) receiving > or =30 embryos were diagnosed to be pregnant, while no pregnancies were established in recipients receiving < or =25 NT embryos. Also, to determine the influence of length of in vitro culture on pregnancy rate, we compared oviductal transfer on day 1 and uterine transfer on day 5, 6, or 7. Pregnancy rates were similar after transfer of embryos on day 1 (6/12; 50.0%), day 5 (4/9; 44.4%), or day 6 (2/5; 40.0%) to synchronous recipients, but the number of fetuses developing after transfer of embryos on day 1 (n = 17), versus day 5 (n = 4) or day 6 (n = 3) was significantly different. Of the 12 pregnant recipients, nine (75%) developed to term and fetal resorption or abortion occurred in the other three (25%) from day 30 to 48 of gestation. Of a total of 17 cloned kittens born, seven were stillborn, eight died within hours of delivery or up to 6 weeks of age, and two are alive and healthy. Perinatal mortality was due to lung immaturity at premature delivery, placental separation and bacterial septicemia. Subsequent DNA analysis of 12 cat-specific microsatellite loci confirmed that all 17 kittens were clones of the AWC donor male. These AWC kittens represent the first wild carnivores to be produced by nuclear transfer.     

Embryo technology in conservation efforts for endangered felids

Most of the 36 species of wild cats are classified as threatened, vulnerable or endangered due to poaching and habitat loss. The important role of assisted reproduction techniques (ART) as part of a multifaceted captive breeding program for selected wild cat species is gradually gaining acceptance. This recognition is a result of the progress made during the last decade in which the feasibility of oocyte recovery from gonadotropin-treated females, in vitro fertilization, embryo cryopreservation and embryo transfer (ET) was demonstrated in the domestic cat (Felis catus). Additionally, embryos have been produced in vitro from oocytes matured in vitro after recovery from ex situ ovaries of both domestic and non-domestic cat species and domestic kittens have been born following transfer of these embryos. In vitro fertilization has been successful in at least one-third of wild cat species and kittens were born after transfer of Indian desert cat (Felis sylvestris ornata) embryos into a domestic cat and con-specific transfer of tiger (Panthera tigris) embryos. The domestic cat is not only a valuable model for development of in vitro techniques but may serve as a recipient of embryos from several species of small wild cats.     

Nuclear transfer of synchronized african wild cat somatic cells into enucleated domestic cat oocytes

The African wild cat is one of the smallest wild cats and its future is threatened by hybridization with domestic cats. Nuclear transfer, a valuable tool for retaining genetic variability, offers the possibility of species continuation rather than extinction. The aim of this study was to investigate the ability of somatic cell nuclei of the African wild cat (AWC) to dedifferentiate within domestic cat (DSH) cytoplasts and to support early development after nuclear transplantation. In experiment 1, distributions of AWC and DSH fibroblasts in each cell-cycle phase were assessed by flow cytometry using cells cultured to confluency and disaggregated with pronase, trypsin, or mechanical separation. Trypsin (89.0%) and pronase (93.0%) yielded higher proportions of AWC nuclei in the G0/G1 phase than mechanical separation (82.0%). In contrast, mechanical separation yielded higher percentages of DSH nuclei in the G0/G1 phase (86.6%) than pronase (79.7%) or trypsin (74.2%) treatments. In both species, pronase induced less DNA damage than trypsin. In experiment 2, the effects of serum starvation, culture to confluency, and exposure to roscovitine on the distribution of AWC and DSH fibroblasts in various phases of the cell cycle were determined. Flow cytometry analyses revealed that the dynamics of the cell cycle varied as culture conditions were modified. Specifically, a higher percentage of AWC and DSH nuclei were in the G0/G1 phase after cells were serum starved (83% vs. 96%) than were present in cycling cells (50% vs. 64%), after contact inhibition (61% vs. 88%), or after roscovitine (56% vs. 84%) treatment, respectively. In experiment 3, we evaluated the effects of cell synchronization and oocyte maturation (in vivo vs. in vitro) on the reconstruction and development of AWC-DSH- and DSH-DSH-cloned embryos. The method of cell synchronization did not affect the fusion and cleavage rate because only a slightly higher percentage of fused couplets cleaved when donor nuclei were synchronized by serum starvation (83.0%) than after roscovitine (80.0%) or contact-inhibition (80.0%). The fusion efficiency of in vivo and in vitro matured oocytes used as recipient cytoplasts of AWC donor nuclei (86.6% vs. 85.2%) was similar to the rates obtained with DSH donor nuclei, 83.7% vs. 73.0%, respectively. The only significant effect of source of donor nucleus (AWC vs. DSH) was on the rate of blastocyst formation in vitro. A higher percentage of the embryos derived from AWC nuclei developed to the blastocyst stage than did embryos produced from DSH nuclei, 24.2% vs. 3.3%, respectively (P < 0.05). In experiment 4, the effect of calcium in the fusion medium on induction of oocyte activation and development of AWC-DSH-cloned embryos was determined. The presence of calcium in the fusion medium induced a high incidence of cleavage of DSH oocytes (54.3%), while oocyte cleavage frequency was much lower in the absence of calcium (16.6%). The presence or absence of calcium in the fusion medium did not affect the fusion, cleavage, and blastocyst development of AWC-DSH-cloned embryos. In experiment 5, AWC-DSH-cloned embryos were transferred to the uteri of 11 synchronized domestic cat recipients on Day 6 or 7 after oocyte aspiration. Recipients were assessed by ultrasonography on Day 21 postovulation, but no pregnancies were observed. In the present study, after NT, AWC donor nuclei were able to dedifferentiate in DSH cytoplasts and support high rates of blastocyst development in vitro. Incomplete reprogramming of the differentiated nucleus may be a major constraint to the in vivo developmental potential of the embryos.     

Somatic cell nuclear transfer in domestic cat oocytes treated with IGF-I for in vitro maturation

Oocyte maturation and somatic cell nuclear transfer (NT) studies conducted in the domestic cat can provide valuable insights that are relevant to the conservation of endangered species of felids. The present investigation focuses on the in vitro maturation (IVM) of domestic cat oocytes stimulated by insulin-like growth factor-I (IGF-I) and their possible use as recipient cytoplasts for somatic cell NT. In Experiment I, the effects of IGF-I on cat oocyte IVM were monitored. Cumulus-oocyte complexes (COCs) were recovered in TALP-HEPES medium following ovarian follicular aspiration and were classified under a stereomicroscope into four grades using criteria based on cumulus cell investment and the uniformity of ooplasm. The COCs were either cultured in Dulbecco's modified Eagle medium (DMEM) alone as a control group or supplemented with 100 ng/ml IGF-I. After culturing for 32-34 h, oocytes were denuded and maturation rate was evaluated by observing the extrusion of the first polar body and staining with aceto-orcein. The percentages of maturation of Grades 1 and 2 oocytes were significantly increased (P<0.05) in IGF-I supplemented medium compared with medium alone (85.8 versus 65.5 and 70.3 versus 51.8, respectively) whereas the maturation rates of Grades 3 and 4 oocytes were not different. The IVM of Grade 1 oocytes was significantly higher (P<0.05) than for all other grades in both control and experimental groups. In Experiment II, the in vitro development of cat NT embryos using cumulus cells, fetal or adult fibroblasts as donor nuclei was investigated. The IVM oocytes in medium containing IGF-I were enucleated and fused with cumulus cells, fetal or adult fibroblasts between passages 2 and 4 of culture. Reconstructed embryos were cultured and monitored every 24h for progression of development through Day 9. There was no significant difference in the percentage of fusion of NT embryos using different donor nuclei whereas the cleavage rates of NT embryos reconstructed with fetal fibroblasts and cumulus cells were significantly higher (P<0.05) than those reconstructed with adult fibroblasts (72.5 and 70.7% versus 54.8%, respectively). Development of NT embryos reconstructed with adult fibroblast to the morula stage was significantly lower (P<0.05) compared with cumulus cell or fetal fibroblast donor cells (25.8% versus 37.9 or 47.5%, respectively). However, no difference was observed in development to the blastocyst stage. These results demonstrated that IGF-I promoted the IVM of domestic cat oocytes. The enucleated IVM oocytes could be used as recipient cytoplasm for fetal and adult somatic cell nuclei resulting in the production of cloned cat embryos.     

Genetic reprogramming of lactate dehydrogenase, citrate synthase, and phosphofructokinase mRNA in bovine nuclear transfer embryos produced using bovine fibroblast cell nuclei

Adult animal cloning has progressed to allow the production of offspring cloned from adult cells, however many cloned calves die prenatally or shortly after birth. This study examined the expression of three important metabolic enzymes, lactate dehydrogenase (LDH), citrate synthase, and phosphofructokinase (PFK), to determine if their detection in nuclear transfer (NT) embryos mimics that determined for in vitro produced embryos. A day 40 nuclear transfer produced fetus derived from an adult cell line was collected and fetal fibroblast cultures were established and maintained. Reconstructed NT embryos were then produced from this cell line, and RT-PCR was used to evaluate mRNA reprogramming. All three mRNAs encoding these enzymes were detected in the regenerated fetal fibroblast cell line. Detection patterns were first determined for IVF produced embryos (1-cell, 2-cell, 6-8 cell, morula, and blastocyst stages) to compare with their detection in NT embryos. PFK has three subunits: PFK-L, PFK-M, and PFK-P. PFK-L and PFK-P were not detected in bovine oocytes. PFK subunits were not detected in 6-8 cell embryos but were detected in blastocysts. Results from NT embryo RT-PCR demonstrated that PFK was not detected in 8-cell NT embryos but was detected in NT blastocysts indicating that proper nuclear reprogramming had occurred. Citrate synthase was detected in oocytes and throughout development to the blastocyst stage in both bovine IVF and NT embryos. LDH-A and LDH-B were detected in bovine oocytes and in all stages of IVF and NT embryos examined up to the blastocyst stage. A third subunit, LDH-C was not detected at the blastocyst stage in IVF or NT embryos but was detected in all earlier stages and in mature oocytes. In addition, LDH-C mRNA was detected in gonad isolated from the NT and an in vivo produced control fetus. These results indicate that the three metabolic enzymes maintain normal expression patterns and therefore must be properly reprogrammed following nuclear transfer.     

Intergeneric somatic cell nucleus transfer in marbled cat and flat-headed cat

Intergeneric nucleus transfer (ig-NT) is a promising technique to produce offspring of endangered species. The objectives of this study were to (1) investigate the in vitro development of marbled cat (MC; Pardofelis marmorata) and flat-headed cat (FC; Prionailurus planiceps) ig-NT embryos reconstructed from domestic cat (DC; Felis catus) oocytes (Experiment 1), (2) evaluate the effect of individual FC donor cell lines on NT success (Experiment 2), and (3) assess the developmental ability of FC-cloned and DC-IVF embryos in vitro and in vivo after oviductal transfer (Experiment 3). In Experiment 1, the morula rate of FC-reconstructed embryos was significantly higher than those of MC and DC embryos but lower than that of parthenogenic DC embryos. However, blastocyst rate was not different. In Experiment 2, FC-ig-NT embryos reconstructed from female muscular tissue had significantly higher morula rate in comparison with those derived from other donor cell lines. However, there was no difference in blastocyst rate among cell lines. In Experiment 3, in vitro development of FC-ig-NT embryos was lower than that of DC-IVF embryos. The competency of in vivo development of FC-ig-NT and/or DC-IVF embryos was investigated by assessing pregnancy rate after their transfer into DC recipients. Domestic cat recipients receiving only FC-ig-NT embryos, FC-ig-NT embryos in one side of the oviduct and DC-IVF embryos contralaterally (co-transfer), and only DC-IVF embryos were observed. No pregnancy was detected in all recipients receiving FC-ig-NT embryos. One recipient receiving co-transferred embryos became pregnant, then delivered DC-IVF dead fetuses (n = 2) and live kittens (n = 6). All recipients receiving DC-IVF embryos became pregnant, and three of six recipients delivered five DC-IVF kittens. These results illustrate the developmental capacity of MC- and FC-ig-NT embryos up to the blastocyst stage. Individual donor cell line affects the developmental success up to the morula stage of FC-ig-NT embryos. Improving the developmental competence and quality of FC-ig-NT embryos may be required for implantation and development to term of FC-ig-NT offspring.     

Current progress on assisted reproduction in dogs and cats: in vitro embryo production

The objective of the development of assisted reproduction techniques in dogs and cats is their application to non-domestic canine and feline species, most of which are considered threatened or endangered. Among these techniques, an entirely in vitro system for embryo production is effectively an important tool for conservation of wildlife. In the last decade, progress has been made in embryo production in carnivores. It has been shown that canine oocytes can resume meiosis in vitro and that these oocytes can be fertilized and developed in vitro, although at a much lower rate than most other domestic animal oocytes. The reason lies in the dissimilarities of reproductive physiology of the dog compared to other species and the lack of precise information concerning the oviductal environment, in which oocyte maturation, fertilization and early embryonic development take place. Successful in vitro embryo production in the domestic cat has been attained with oocytes matured in vitro, and kittens were born after transfer of IVM/IVF derived embryos. On the basis of these results the in vitro fertilization of oocytes has also been applied in several non-domestic feline species. The effectiveness of such protocols in the preservation of genetic material of rare species can be improved by developing better techniques for long-term storage of gametes. In dogs and cats sperm cells have been successfully frozen and the cryopreservation of oocytes would greatly increase their availability for a range of reproductive technologies. Cryopreserved cat oocytes can be fertilized successfully and their development in vitro after fertilization is enhanced when mature oocytes are frozen. Thus refined techniques of oocyte maturation and fertilization in vitro coupled with oocyte cryopreservation could allow for an easy establishment of genetic combinations when male and female gametes in the desired combination are not simultaneously available, and the propagation of endangered carnivores would be facilitated.     

Nuclear and microtubule remodeling and in vitro development of nuclear transferred cat oocytes with skin fibroblasts of the domestic cat (Felis silvestris catus) and leopard cat (Prionailurus bengalensis)

The leopard cat (Prionailurus bengalensis), a member of the felidae family, is a threatened animal in South Korea. In terms of protecting endangered felids, nuclear transfer (NT) is a potentially valuable technique for assuring the continuation of species with dwindling numbers. In the present experiment, nuclear and microtubule remodeling and the in vitro developmental potential of enucleated domestic cat oocytes reconstructed with nuclei of somatic cells from either domestic cat fibroblast (DCF) or leopard cat fibroblast (LCF) were evaluated. Microtubule aster is allocated to de-condensed chromatin following nuclear transfer (3h after activation) of fibroblast cells from both domestic and leopard cats, suggesting the introduction of a somatic cell centrosome. The transferred fibroblast nuclei formed a large, swollen, pronuclear-like structure in most reconstructed oocytes, in the cat or leopard cat. At 18h following nuclear transfer, mitosis occurred, and according to the photo (F) it appears that spindle microtubules and two asters were observed. The percentages of blastocyst formation from nuclear transfer embryos derived from domestic cat fibroblasts (4/46, 8.6%) were not significantly different than those for nuclear transfer embryos constructed with leopard cat fibroblasts (4/52, 7.6%). These results indicate that nuclear and microtubule remodeling processes and in vitro developmental ability are similar in reconstructed cat oocytes following transfer of nuclei from either domestic or leopard cats.     

Production of second-generation cloned cats by somatic cell nuclear transfer

We successfully produced second-generation cloned cats by somatic cell nuclear transfer (SCNT) using skin cells from a cloned cat. Skin cells from an odd-eyed, all-white male cat (G0 donor cat) were used to generate a cloned cat (G1 cloned cat). At 6 months of age, skin cells from the G1 cloned cat were used for SCNT to produce second-generation cloned cats. We compared the in vitro and in vivo development of SCNT embryos that were derived from the G0 donor and G1 cloned donor cat's skin fibroblasts. The nuclei from the G0 donor and G1 cloned donor cat's skin fibroblasts fused with enucleated oocytes with equal rates of fusion (60.7% vs. 58.8%, respectively) and cleavage (66.3% vs. 63.4%). The 2-4-cell SCNT embryos were then transferred into recipients. One of the five recipients of G0 donor derived NT embryos (20%) delivered one live male cloned kitten, whereas 4 of 15 recipients of the G1 cloned donor cat derived NT embryos (26%) delivered a total of seven male second-generation cloned kittens (four live kittens from one surrogate, plus two stillborn kittens, and one live kitten that died 2d after birth from three other surrogate mothers). The four second-generation cloned kittens from the same surrogate all had a white coat color; three of the four second-generation cloned kittens had two blue eyes, and one of the second-generation cloned kittens had an odd-eye color. Despite low cloning efficiency, cloned cats can be used as donor cats to produce second-generation cloned cats.     

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.     

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.     

Chromosomal aneuploidy in African Wildcat somatic cells and cloned embryos

In the present study, we compared the incidence of aneuploidy in in vitro fertilized domestic cat embryos (DSH-IVF) with that of African Wildcat (AWC) cloned embryos reconstructed with AWC fibroblast donor cells from different passages (AWC-NT). Fibroblast cells were cultured to passages 1 (P1), 3 (P3), 4 (P4), and 9 (P9), after which cells at each passage were karyotyped and serum-starved before being frozen for nuclear transfer. AWC-NT embryos were produced by fusion of a single AWC somatic cell at P1, P3, P4, or P9 to enucleated domestic cat cytoplast derived from in vitro matured (IVU) oocytes. DSH-IVF embryos were produced after IVU oocytes were fertilized in vitro with domestic cat spermatozoa. To determine chromosome numbers, embryos (2-4-cell) or fibroblast cells were cultured in medium containing 0.28 microg/mL of Colcemid for 22-24 h or 15-24 h, respectively. Subsequently, embryos and cells were placed in hypotonic solution, fixed, and stained for analysis of chromosome spreads by bright field microscopy. Chromosomal abnormalities in AWC fibroblast cells increased progressively during culture in vitro: P1 (43%), P3 (46%), P4 (62%), and P9 (59%). In fibroblast cells, hypoploidy (94/202, 46%) was the major chromosomal abnormality, and it occurred more frequently than hyperploidy (14/202, 7%; p < 0.05). While the percentage of hyperploid cells remained stable during all passages, the proportion of hypoploidy in fibroblast cells increased significantly after P4. The overall incidence of chromosomal abnormalities in AWC-NT embryos at P1 (45%), P3 (60%), and P4 (50%) was similar to that of the fibroblast cells from which they were derived; however, the incidence was higher for embryos reconstructed with donor fibroblasts at P9 (89%). Hypoploidy was the most common chromosomal abnormality observed in either AWC-NT or DSH-IVF embryos. AWCNT embryos reconstructed with donor cells at early passages (P1, P3, and P4) had similar frequencies of chromosomal diploidy, as did DSH-IVF embryos. Accordingly, based on the present results, for NT we are currently using cat donor cells at early passages, when the percentage of cells with chromosomal abnormalities is low. It is recommended that the chromosomal stability of each cell line be analyzed before use as NT donor cells to reduce the incidence of chromosomal anomalies in reconstructed embryos and to possibly produce a subsequent increase in cloning efficiency.     

In vitro production and initiation of pregnancies in inter-genus nuclear transfer embryos derived from leopard cat (Prionailurus bengalensis) nuclei fused with domestic cat (Felis silverstris catus) enucleated oocytes

The leopard cat (Prionailurus bengalensis), a member of the felidae family, is currently listed as threatened by the Ministry of Environment in South Korea. In exotic or endangered species, the lack of oocytes and recipients precludes the use of traditional somatic cell nuclear transfer, and an approach such as inter-genus nuclear transfer may be the only alternative for producing embryos and offspring. In the present study, we used the leopard cat as a somatic cell donor to evaluate the in vivo developmental competence, after transfer into domestic cat recipients, of cloned embryos produced by the fusion of leopard cat fibroblast cell nuclei with domestic cat cytoplasts. A total of 412 enucleated domestic cat oocytes were reconstructed with either male (Group A) or female (Group B) adult leopard cat fibroblasts. There was no significant difference in fusion rate (60.4% versus 56.9%) between Groups A and B. Of the cultured embryos, the cleavage and blastocyst developmental rate were not significantly different between Groups A and B (69.5% versus 60.8%; 7.2% versus 7.8%, P > 0.05). In Group A, in vivo developmental studies at 30-45 days postimplantation demonstrated 4.8% (21/435) of reconstructed embryos (n = 435) had entered into the uterine lining of recipients, while 1.4% (6/435) formed fetuses. However, all of the reconstructed embryos failed to develop to term (65 days). Microsatellite analyses confirmed that the nuclear genome of the cloned fetus were leopard cat in origin.     

Developmental competence of somatic cell nuclear transfer embryos reconstructed from oocytes matured in vitro with follicle shells in miniature pig

The developmental competence of domestic pig oocytes that were transferred to somatic cell nuclei of miniature pig was examined. A co-culture system of oocytes with follicle shells was used for the maturation of domestic pig oocytes in vitro. Co-cultured oocytes progressed to the metaphase II stage of meiosis more quickly and more synchronously than non co-cultured oocytes. Oocytes were enucleated and fused with fibroblast cells of Potbelly miniature pig at 48 h of maturation. The blastocyst formation rate of nuclear transfer (NT) embryos using cocultured oocytes (24%) was significantly higher (p < 0.05) than that of non-co-cultured oocytes (13%). Cleaved embryos at 48 h after nuclear transfer using co-cultured oocytes were transferred to the oviducts of 14 G?ttingen miniature pigs and four Meishan pigs. Estrus of all G?ttingens returned at around 20-31 days of pregnancy. Two of the four Meishans became pregnant. Three and two cloned piglets were born after modest number of embryo transfer (15 and 29 embryos transferred), respectively. These results indicated that oocytes co-cultured with follicle shells have a high developmental competence after nuclear transfer and result in full-term development after embryo transfer.     

Nuclear transfer in cattle: Effect of nuclear donor cells,cytoplast age,co-culture,and embryo transfer

There are many factors affecting the efficiency of nuclear transfer technology. Some are evaluated here using our novel approach by enucleating oocytes at 20–22 hr after in vitro maturation (IVM), culturing the enucleated oocytes (cytoplasts) for 8–10 hr or 18–20 hr to gain activation competence and then conducting nuclear transfer. In the first experiment, we demonstrated that cumulus cell (CC) monolayer can support some cloned embryos to develop into morulae or blastocysts. Co-culture with CC and bovine oviduct epithelial cell (BOEC) monolayers resulted in no differences (P 0.05) in supporting the development of cloned embryos (Experiment 2). When in vitro matured oocytes were enucleated at 22 hr after IVM followed by nuclear transfer 18–20 hr later, cleavage and morula or blastocyst development of the cloned embryos were similar to those resulting from the enucleated oocytes which had been matured in vivo (Experiment 3). Frozen embryos as nuclear donor cells worked equally well as fresh embryos for cloning in embryo development which was superior to IVF embryos (Experiment 4). However, fresh embryos resulted in a higher proportion (P < 0.05) of blastomere recovery than did frozen or IVF ambryos. Finally, embryo transfer of cloned embryos from our procedure produced a viable calf, demonstrating the commercial value of this novel approach of the technology. © 1993 Wiley-Liss, Inc.     

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.     

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 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.     

In vitro development of the reconstructed bovine embryos activated at various time after electrofusion

The dynamics of in vitro development of reconstructed bovine embryos activated at various time after electrofusion was studied. The in vitro mature oocytes without zona pellucida enucleated using the blind method were taken as cytoplasts. Fetal fibroblasts were used as the nuclei source. Approximately 40% of embryos activated between 3 and 3.2 hours after electrofusion developed to blastocysts. The efficiency of in vitro development of cloned embryo of cloned embryo did not decrease when the time between electrofusion and activation was extended up to 4–5 hours. The pattern of more successful development of in vitro reconstructed embryos was found using enucleated oocytes, extrusion the first polar body to 18 hours in comparison with oocytes matured in vitro afterwards, as cytoplasts.     

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.