Blastocysts produced by nuclear transfer between chicken blastodermal cells and rabbit oocytes.

Interspecies nuclear transfer (INT) has been used as an invaluable tool for studying nucleus-cytoplasm interactions; and it may also be a method for rescuing endangered species whose oocytes are difficult to obtain. In the present study, we investigated interaction of the chicken genome with the rabbit oocyte cytoplasm. When chicken blastodermal cells were transferred into the perivitelline space of rabbit oocytes, 79.3% of the couplets were fused and 9.7% of the fused embryos developed to the blastocyst stage. Both M199 and SOF medium were used for culturing chicken-rabbit cloned embryos; embryo development was arrested at the 8-cell stage obtained in SOF medium, while the rates of morulae and blastocysts were 12.1 and 9.7%, respectively, in M199 medium. Polymerase chain reaction (PCR) amplification of nuclear DNA and karyotype analyses confirmed that genetic material of morulae and blastocysts was derived from the chicken donor cells. Analysis mitochondrial constitution of the chicken-rabbit cloned embryos found that mitochondria, from both donor cells and enucleated oocytes, co-existed. Our results suggest that: (1) chicken genome can coordinate with rabbit oocyte cytoplasm in early embryo development; (2) there may be an 8- to 16-cell stage block for the chicken-rabbit cloned embryos when cultured in vitro; (3) mitochondrial DNA from the chicken donor cells was not eliminated until the blastocyst stage in the chicken-rabbit cloned embryos; (4) factors existing in ooplasm for somatic nucleus reprogramming may be highly conservative.

Quantitative analysis of mitochondrial DNAs in macaque embryos reprogrammed by rabbit oocytes.

In cloned animals where somatic cell nuclei and oocytes are from the same or closely related species, the mitochondrial DNA (mtDNA) of the oocyte is dominantly inherited. However, in nuclear transfer (NT) embryos where nuclear donor and oocyte are from two distantly related species, the distribution of the mtDNA species is not known. Here we determined the levels of macaque and rabbit mtDNAs in macaque embryos reprogrammed by rabbit oocytes. Quantification using a real-time PCR method showed that both macaque and rabbit mtDNAs coexist in NT embryos at all preimplantation stages, with maternal mtDNA being dominant. Single NT embryos at the 1-cell stage immediately after fusion contained 2.6 x 10(4) copies of macaque mtDNA and 1.3 x 10(6) copies of rabbit mtDNA. Copy numbers of both mtDNA species did not change significantly from the 1-cell to the morula stages. In the single blastocyst, however, the number of rabbit mtDNA increased dramatically while macaque mtDNA decreased. The ratio of nuclear donor mtDNA to oocyte mtDNA dropped sharply from 2% at the 1-cell stage to 0.011% at the blastocyst stage. These results suggest that maternal mtDNA replicates after the morula stage.

Mitochondrial DNA heteroplasmy in calves cloned by using adult somatic cell.

Adult somatic cell cloned calves were produced by somatic cell nuclear transfer prepared by fusion of cultured ear fibroblast from a Holstein cow into enucleated oocytes of Luxi Yellow cow. In order to determinate the source of mitochondrial DNA of cloned calves, we designed the breed-specific PCR primers by aligning the known D-loop sequences of Bos taurus and analyzed the displacement loop sequences of five live cloned calves by breed-specific primers PCR. The results demonstrated that mtDNA originated from Holstein breed and that from Luxi breed co-exist in all five live calves.

In vitro development and mitochondrial fate of macaca-rabbit cloned embryos.

Interspecies cloning may be used as an effective method to conserve highly endangered species and to support the development of non-human primate animal models for studying therapeutic cloning and nuclear-cytoplasm interaction. The use of the monkey model for biomedical research can avoid legal, ethical, and experimental limitations encountered in a clinical situation. We describe in this study the in vitro development of macaca-rabbit embryos produced by fusing macaca fibroblasts with enucleated rabbit oocytes and examine the fate of mitochondrial DNA in these embryos. We show that macaca-rabbit cloned embryos can develop to the blastocyst stage when cultured in vitro in HECM(10) +10% FBS and that mitochondrial DNA derived from donor somatic cells was detectable in cloned embryos throughout preimplantation development. These results suggest that (1) macaca fibroblast nuclei can dedifferentiate in enucleated metaphase II rabbit oocytes; (2) HECM(10) +10% FBS can break through the development block and support the development of macaca-rabbit cloned embryos to blastocysts; and (3) donor-cell-derived mitochondrial DNA is not eliminated until blastocyst stage.

Comparison of developmental capacity for intra- and interspecies cloned cat (Felis catus) embryos.

Interspecies nuclear transfer is an invaluable tool for studying nucleus-cytoplasm interactions; and at the same time, it provides a possible alternative to clone animals whose oocytes are difficult to obtain. In the present study, we investigated the possibility of cloning cat embryos using rabbit oocytes, and compared the developmental capacity; the timing of embryogenesis of the cat-rabbit cloned embryos with that of the cat-cat or the rabbit-rabbit cloned embryos. When cultured in M199, the rate of blastocyst formation of the cat-rabbit embryos was 6.9%, which was not significantly different than that of the cat-cat embryos (10.5%). However, the rate of blastocyst formation of rabbit-rabbit embryos (22.9%) was significantly greater than that of both the cat-rabbit and the cat-cat embryos (P < 0.05). The timing of the first three cleavages for the cat-rabbit embryos was similar to that of the rabbit-rabbit embryos, but significantly faster than that of the cat-cat embryos (P < 0.05), while the time to form blastocysts was similar to that of cat-cat embryos, but significantly slower than that of the rabbit-rabbit embryos (P < 0.05). Both M199 and SOF medium were evaluated for culturing cat-rabbit embryos; the rate of blastocyst formation in SOF (14.5%) was significantly greater than that in M199 (6.9%) (P < 0.05). These results demonstrate that: (1) the cat-rabbit embryos possess equal developmental capacity as cat-cat embryos; (2) the timing of the first three cleavages for the cat-rabbit embryos is recipient-specific, while the time to form blastocysts is donor nucleus-specific; and (3) SOF medium may be beneficial to overcome the morula-to-blastocyst block for cat-rabbit cloned embryos.

The effects of different donor cells and passages on development of reconstructed embryos.

In order to study the effects of different donor cells and passages on development of nuclear transfer embryos, we constructed embryos by electrofusing several kinds of donor cells into enucleated M II oocytes from Kun Ming (KM) mouse. These cells include 2-cell embryonic blastomeres, KMW embryonic stem (ES) cells, fetal fibroblast, ear fibroblast, tail tip fibroblast, sertoil cells and spermatogonia. Meanwhile, we compared the effects of passage numbers of fetal fibroblast cells on developmental competency after nuclear transfer. We found that 7.4% of reconstructed embryos from 2-cell embryonic blastomeres and 0.7% from ES cell could develop to blastocyst in vitro; embryos from fetal fibroblast could only develop to morula stage with the rate of 0.2%; embryos from spermatogonia could only develop to 8-cell stage and the rate was 0.3%; embryos respectively from ear fibroblast, sertoli cell and tail tip fibroblast could only develop to 4-cell stage. Although 2-cell development rate of embryos reconstructed from fetal fibroblast in first passage was significantly lower than those from the 2nd, the 3rd and the 4th passage, embryos from different passages could develop to 8-cell stage except the 3rd passage. The result indicated that it is more difficult for terminally differentiated cell nuclei to be reprogrammed in enucleated M II oocytes than for low differentiated cell nuclei. The reason of low development rate from ES cells maybe that most of ES cells was at S stage of the cell cycle, which out of coordination with M II oocytes. We could conclude that culture and passage of donor cells might be benefit to nucleus reprogramming.

Interspecies implantation and mitochondria fate of panda-rabbit cloned embryos.

Somatic cell nuclei of giant pandas can dedifferentiate in enucleated rabbit ooplasm, and the reconstructed eggs can develop to blastocysts. In order to observe whether these interspecies cloned embryos can implant in the uterus of an animal other than the panda, we transferred approximately 2300 panda-rabbit cloned embryos into 100 synchronized rabbit recipients, and none became pregnant. In another approach, we cotransferred both panda-rabbit and cat-rabbit interspecies cloned embryos into the oviducts of 21 cat recipients. Fourteen recipients exhibited estrus within 35 days; five recipients exhibited estrus 43-48 days after embryo transfer; and the other two recipients died of pneumonia, one of which was found to be pregnant with six early fetuses when an autopsy was performed. Microsatellite DNA analysis of these early fetuses confirmed that two were from giant panda-rabbit cloned embryos. The results demonstrated that panda-rabbit cloned embryos can implant in the uterus of a third species, the domestic cat. By using mitochondrial-specific probes of panda and rabbit, we found that mitochondria from both panda somatic cells and rabbit ooplasm coexisted in early blastocysts, but mitochondria from rabbit ooplasm decreased, and those from panda donor cells dominated in early fetuses after implantation. Our results reveal that mitochondria from donor cells may substitute those from recipient oocytes in postimplanted, interspecies cloned embryos.

[Effects of different treatments on oocytes activation and parthenogenesis in mouse].

In order to study effects of electro-fusion and strontium chloride (SrCl2) activation in nuclear transfer experiment on activation and development of mouse oocytes, concentration and treatment duration of SrCl2, electro-pulse and electro-pulse combining SrCl2 were used to activate mouse oocytes which were obtained after hCG 17h. Activated oocytes were cultured in vitro in CZB medium. The results were as follows: 82.4% activation percentage was obtained when the oocytes were treated with 10mmol/L SrCl2 for 6h, it was significantly (P>0.05) higher than those obtained from that treated with the 5mmol/L or 10mmol/L SrCl2 for 4h. The activation percentage was not significantly different between 5mmol/L and 10mmol/L SrCl2 for 6h, but the percentage of morula and blastocyst in 10mmol/L SrCl2 6h group was significantly (P > 0.05) higher than those in 5mmol/L SrCl2 6h group. In the groups of treatment with electro-pulse, the best activation percentage (70.9%) was obtained when the oocytes were treated with 1.0kv/cm, 320micros, 3 pulses, but M + B percentage (7.9%) was low. In the groups of treatment with electro-pulse combining with SrCl2, the best result was acquired (activation and M + B percentage were 75.0% and 57.3% separately) when the oocytes were treated in 10mmol/L SrCl2 for 6h interval 1h after treated with 1.8kv/cm, 10s, 1pulse. These results show that the treatment with electro-pulse combining SrCl2 is a better way to mouse parthenogenesis.