Endangered wolves cloned from adult somatic cells

Over the world, canine species, including the gray wolf, have been gradually endangered or extinct. Many efforts have been made to recover and conserve these canids. The aim of this study was to produce the endangered gray wolf with somatic cell nuclear transfer (SCNT) for conservation. Adult ear fibroblasts from a female gray wolf (Canis lupus) were isolated and cultured in vitro as donor cells. Because of limitations in obtaining gray wolf matured oocytes, in vivo matured canine oocytes obtained by flushing the oviducts from the isthmus to the infundibulum were used. After removing the cumulus cells, the oocyte was enucleated, microinjected, fused with a donor cell, and activated. The reconstructed cloned wolf embryos were transferred into the oviducts of the naturally synchronized surrogate mothers. Two pregnancies were detected by ultrasonography at 23 days of gestation in recipient dogs. In each surrogate dog, two fetal sacs were confirmed by early pregnancy diagnosis at 23 days, but only two cloned wolves were delivered. The first cloned wolf was delivered by cesarean section on October 18, 2005, 60 days after embryo transfer. The second cloned wolf was delivered on October 26, 2005, at 61 days postembryo transfer. Microsatellite analysis was performed with genomic DNA from the donor wolf, the two cloned wolves, and the two surrogate female recipients to confirm the genetic identity of the cloned wolves. Analysis of 19 microsatellite loci confirmed that the cloned wolves were genetically identical to the donor wolf. In conclusion, we demonstrated live birth of two cloned gray wolves by nuclear transfer of wolf somatic cells into enucleated canine oocyte, indicating that SCNT is a practical approach for conserving endangered canids.     

A cloned toy poodle produced from somatic cells derived from an aged female dog

To date, dogs have been cloned with somatic cell nuclear transfer (SCNT), using donor cells derived from large-breed dogs 2 months to 3 years of age. The objective of the present study was to use SCNT to produce a small-breed dog from ear fibroblasts of an aged poodle, using large-breed oocyte donors and surrogate females, and to determine the origin of its mitochondrial DNA (mtDNA) and the length of its telomeres. Oocytes were derived from large-breed donors, matured in vivo, collected by flushing oviducts, and reconstructed with somatic cells derived from an aged (14-year-old) female toy poodle. Oocytes and donor cells were fused by electric stimuli, activated chemically, and transferred into the oviducts of large-breed recipient females. Overall, 358 activated couplets were surgically transferred into the oviducts of 20 recipient dogs. Two recipients became pregnant; only one maintained pregnancy to term, and a live puppy (weighing 190 g) was delivered by Caesarean section. The cloned poodle was phenotypically and genetically identical to the nuclear donor dog; however, its mtDNA was from the oocyte donor, and its mean telomere length was not significantly different from that of the nuclear donor. In summary, we demonstrated that a small-breed dog could be cloned by transferring activated couplets produced by fusion of somatic cells from a small-breed, aged donor female with enucleated in-vivo-matured oocytes of large-breed females, and transferred into the oviduct of large-breed recipient female dogs.     

Birth of viable female dogs produced by somatic cell nuclear transfer

Since the only viable cloned offspring born in dogs was a male, the purpose of the present study was to produce female puppies by somatic cell nuclear transfer (SCNT). Adult ear fibroblasts from a 2-month-old female Afghan hound were isolated and used as donor cells. In vivo-matured canine oocytes surgically collected (approximately 72h after ovulation) from the oviducts of 23 donors were used for SCNT. After removal of the cumulus cells, oocytes were enucleated, microinjected, fused with a donor cell, and activated. A total of 167 reconstructed SCNT embryos were surgically transferred (Day 0) into the oviducts of 12 recipient bitches (average 13.9 embryos/recipient, range 6-22) with spontaneous, synchronous estrous cycles. Three pregnancies were detected by ultrasonography on Day 23, maintained to term, and three healthy female puppies (520, 460, and 520g), were delivered by Caesarean section on Day 60. These puppies were phenotypically and genotypically identical to the cell donor. In conclusion, we have provided the first demonstration that female dogs can be produced by nuclear transfer of ear fibroblasts into enucleated canine oocytes.     

Improved efficiency of canine nucleus transfer using roscovitine-treated canine fibroblasts

The aim of this study was to investigate whether roscovitine (the cyclin-dependent kinase 2 inhibitor) effectively induces synchronization of the donor cell cycle at G0/G1 and to examine the effect of donor cell cycle synchronization protocols on canine somatic cell nucleus transfer. Canine fibroblasts were obtained from skin biopsy cultures taken from a 7-yr-old retriever. The donor cell cycle was synchronized either by culturing cells to reach confluency or by treating cells with 15 μg/mL roscovitine for 24 h. Cell cycle stages and apoptosis were analyzed by flow cytometry. After synchronization of the donor cell cycle, cells were placed with enucleated in vivo-matured dog oocytes, fused by electric stimulation, activated, and transferred into 18 naturally estrus-synchronized surrogates. There was no significant difference in cell cycle synchronization and apoptosis rates between the confluent and roscovitine groups. After transfer of reconstructed embryos, pregnancy was detected in three of nine surrogates that received cloned embryos reconstructed with roscovitine-treated cells, whereas only one of nine surrogates was pregnant after transfer of cloned embryos reconstructed with confluent cells. One pregnant female from the confluent cell group delivered one live and one dead pup, but the live one died within 5 days after birth. Three pregnant females from the roscovitine-treated cell group delivered eight live pups and one dead pup, and one of eight live pups died within 6 days after birth. In conclusion, the current results demonstrated that reconstructing embryos with roscovitine-treated cells resulted in increased efficiency of canine somatic cell nucleus transfer.     

Two-staged nuclear transfer can enhance the developmental ability of goat�Csheep interspecies nuclear transfer embryos in vitro

The technique of interspecies somatic cell nuclear transfer, in which interspecies cloned embryos can be reconstructed by using domestic animal oocytes as nuclear recipients and endangered animal or human somatic cells as nuclear donors, can afford more opportunities in endangered animal rescue and human tissue transplantation, but the application of this technique is limited by extremely low efficiency which may be attributed to donor nucleus not fully reprogrammed by xenogenic cytoplasm. In this study, goat fetal fibroblasts (GFFs) were used as nuclear donors, in vitro-matured sheep oocytes were used as nuclear recipients, and a two-stage nuclear transfer procedure was performed to improve the developmental ability of goat-sheep interspecies clone embryos. In the first stage nuclear transfer (FSNT), GFFs were injected into the ooplasm of enucleated sheep metaphase-II oocytes, then non-activated reconstructed embryos were cultured in vitro, so that the donor nucleus could be exposed to the ooplasm for a period of time. Subsequently, in the second stage nuclear transfer, FSNT-derived non-activated reconstructed embryo was centrifuged, and the donor nucleus was then transferred into another freshly enucleated sheep oocyte. Compared with the one-stage nuclear transfer, two-stage nuclear transfer could significantly enhance the blastocyst rate of goat-sheep interspecies clone embryos, and this result indicated that longtime exposure to xenogenic ooplasm benefits the donor nucleus to be reprogrammed. The two-stage nuclear transfer procedure has two advantages, one is that the donor nucleus can be exposed to the ooplasm for a long time, the other is that the problem of oocyte aging can be solved.     

Improvement of the nuclear transfer efficiency by using the same genetic background of recipient oocytes as the somatic donor cells in goats

We have compared the effect of the genetic background of recipient oocytes on the in vitro and in vivo development of nuclear transfer reconstructed embryos in goats. Adult fibroblast cells from Boer goats were used as donor cells, and recipient oocytes were obtained from Boer goats and Boer cross-breeds (Boer♂×Huanghuai♀). Nuclear transfer reconstructed embryos were cultured in vitro, or transferred into recipient goats. The mitochondrial origin of 2 cloned Boer goats was investigated by analysing the D-loop region based on polymorphisms via DNA sequencing. There was no significant difference in the fusion rate and cleavage rate of reconstructed embryos (P>0.05), when using Boer and cross-breeding goat oocytes as recipient cytoplast respectively. However, in vitro morula development of reconstructed embryos from Boer oocytes was significantly higher than that of cross-breeding embryos (34.1% versus 19.1%, P<0.05). There was no significant difference in the rate of pregnancy and foetus loss between the 2 breeds. However, the live-birth rate was significantly higher with Boer goat oocyte recipients than the cross-breeds (3.1% versus 0.8%, P<0.05). Mitochondrial analysis showed that the 2 cloned goats were similar to their respective oocyte donor goats, and significantly different from the nucleus donor. In conclusion, genetic background of recipient oocytes affected in vitro and in vivo development of reconstructed embryos, with the homologous background of cytoplast and nuclear donor benefiting development of reconstructed embryos. The mitochondrial origin of the 2 cloned Boer goats came from recipient oocytes, not donors.     

Factors controlling the loss of immunoreactive somatic histone H1 from blastomere nuclei in oocyte cytoplasm: a potential marker of nuclear reprogramming

Nuclei of differentiated cells can acquire totipotency following transfer into the cytoplasm of oocytes. While the molecular basis of this nuclear reprogramming remains unknown, the developmental potential of nuclear-transfer embryos is influenced by the cell-cycle stage of both donor and recipient. As somatic H1 becomes immunologically undetectable on bovine embryonic nuclei following transfer into ooplasm and reappears during development of the reconstructed embryo, suggesting that it may act as a marker of nuclear reprogramming, we investigated the link between cell-cycle state and depletion of immunoreactive H1 following nuclear transplantation. Blastomere nuclei at M-, G1-, or G2-phase were introduced into ooplasts at metaphase II, telophase II, or interphase, and the reconstructed embryos were processed for immunofluorescent detection of somatic histone H1. Immunoreactivity was lost more quickly from donor nuclei at metaphase than at G1 or G2. Regardless of the stage of the donor nucleus, immunoreactivity was lost most rapidly when the recipient cytoplast was at metaphase and most slowly when the recipient was at interphase. When the recipient oocyte was not enucleated, however, immunoreactive H1 remained in the donor nucleus. The phosphorylation inhibitors 6-DMAP, roscovitine, and H89 inhibited the depletion of immunoreactive H1 from G2, but not G1, donor nuclei. In addition, immunoreactive H1 was depleted from mouse blastomere nuclei following transfer into bovine oocytes. Finally, expression of the developmentally regulated gene, eIF-1A, but not of Gapdh, was extinguished in metaphase recipients but not in interphase recipients. These results indicate that evolutionarily conserved cell-cycle-regulated activities, nuclear elements, and phosphorylation-linked events participate in the depletion of immunoreactive histone H1 from blastomere nuclei transferred in oocyte cytoplasm and that this is linked to changes in gene expression in the transferred nucleus.     

人-山羊异种核移植胚胎发育的初步研究

以体外分离培养的人胚胎成纤维细胞为核供体,经血清饥饿培养后,通过显微操作技术移入山羊去核卵母细胞中,采用化学方法激活重组胚.通过体外培养观察,2-细胞胚胎发育率可达51.33%,4-细胞发育率为31.42%,但发育至桑椹胚阶段的胚胎数目大大减少,仅为9.73%.虽然目前尚未能获得异种核移植囊胚,但实验结果说明山羊成熟卵母细胞可以支持人体细胞核完成重编程,人-山羊异种体细胞核移植重组胚可在体外完成其早期发育.     

山羊品种间体细胞核移植研究

萨能奶山羊是著名的奶用山羊品种,波尔山羊则是世界著名的肉用山羊品种。为了研究波尔山羊体细胞在奶山羊卵母细胞中的去分化,我们针成年波尔山羊的颗粒细胞或耳皮肤成纤维细胞作为供核细胞（试验组）,移入奶山羊中Ⅱ期的去核卵母细胞透明带下,经电融合和离子霉素与6－二甲基氨基嘌呤－DMAP）激活,直接移入同期发情奶山羊输卵管或经体内培养,将发育的重构胚移入同期发情羊子宫内。妊娠早期作B超诊断,确立妊娠的观察至足月。同时将奶山羊的35日龄胎儿成纤维细胞作供核细胞（对照组）,按试验组同样方法处理,将重构胚直接移入同期发情的奶山羊输卵管内。结果：试验组,波尔羊颗粒粒细胞与耳皮肤成纤维2细胞的融合率分别为78．2％（115／147）,57．4％（116／202）,重构胚卵裂率为85．8％（115／134）,桑椹胚,囊胚的发育率38．8％（52／134）,早期妊娠三头,分别于妊娠40,60,60日龄终止妊娠。对照组,融合率为89．5％（136／152）,早期妊娠率为42．9％（6／14）,四头受体足月分娩,产四头公羊羔,其中三头存活,一头分娩时死于肺不扩张,并体重过大,显示胎儿过大综合症。经基因型鉴定证实,这四头克隆羔羊均源于同一胎儿成纤维细胞系。以上结果表明,波尔羊体细胞核在奶山羊卵母细胞中能够去分化,并维持一定程度的发育。     

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.     

山羊品种间体细胞核移植研究

萨能奶山羊是著名的奶用山羊品种,波尔山羊则是世界著名的肉用山羊品种.为了研究波尔山羊体细胞在奶山羊卵母细胞中的去分化,我们将成年波尔山羊的颗粒细胞或耳皮肤成纤维细胞作为供核细胞(试验组),移入奶山羊中Ⅱ期的去核卵母细胞透明带下,经电融合和离子霉素与6-二甲基氨基嘌呤(6-DMAP)激活,直接移入同期发情奶山羊输卵管或经体内培养,将发育的重构胚移人同期发情羊子宫内.妊娠早期作B超诊断,确立妊娠的观察至足月.同时将奶山羊的35日龄胎儿成纤维细胞作供核细胞(对照组),按试验组同样方法处理,将重构胚直接移入同期发情的奶山羊输卵管内.结果试验组,波尔羊颗粒粒细胞与耳皮肤成纤维细胞的融合率分别为78.2%(115/147)、57.4%(116/202),重构胚卵裂率为85.8%(115/134),桑椹胚、囊胚的发育率38.8%(52/134),早期妊娠三头,分别于妊娠40、60、60日龄终止妊娠.对照组,融合率为89.5%(136/152),早期妊娠率为42.9%(6/14),四头受体足月分娩,产四头公羊羔,其中三头存活,一头分娩时死于肺不扩张,并体重过大,显示胎儿过大综合症.经基因型鉴定证实,这四头克隆羔羊均源于同一胎儿成纤维细胞系.以上结果表明,波尔羊体细胞核在奶山羊卵母细胞中能够去分化,并维持一定程度的发育.     

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.     

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.     

Production of cloned goats after nuclear transfer using adult somatic cells.

The developmental potential of adult somatic nuclei after nuclear transfer (NT) into enucleated, in vitro-matured oocytes was evaluated in a dwarf breed of goat (BELE: Breed Early Lactate Early). Somatic donor cells were obtained from two different sources: 1) adult granulosa cells (GCs) and 2) fetal fibroblasts. Primary GCs were obtained from follicular aspirants after laparoscopic oocyte pick-up (LOPU) and were cryopreserved immediately. Frozen aliquots of cells were thawed and cultured until confluent and were then cultured in low serum for 4 days before use in NT. Immature oocytes were obtained by LOPU and matured before enucleation and NT. Ninety-one adult GC-derived NT embryos were transferred into eight recipients, four of which were confirmed pregnant (50%) at Day 30 by ultrasound. Fifty-four male fetal fibroblast-derived NT embryos were transferred into six recipients, one of which was confirmed pregnant (17%). All pregnancies were maintained through term. Four recipients delivered seven female kids (three sets of twins) derived from the GC cultures (7.7% of embryos transferred). The other recipient delivered two male kids (3.7% of embryos transferred). Birth weights were within the normal range for dwarf goats. One female twin and one male twin died at birth; the remaining kids appeared healthy and normal. DNA analysis confirmed that the kids were genetically identical to their respective donors. These results demonstrated that adult caprine somatic cells could direct normal development after NT.     

Birth of rats following nuclear exchange at the 2-cell stage

We report full-term development of nuclear transfer embryos following nuclear exchange at the 2-cell stage. Nuclei from 2-cell rat embryos were transferred into enucleated 2-cell embryos and developed to term after transfer to recipients (NT2). Pronuclear exchange in zygotes was used for comparison (NT1). Zygotes and 2-cell embryos were harvested from 4-week-old female Sprague-Dawley rats. Nuclear transfer was performed by transferring the pronuclei or karyoplasts into the perivitelline space of recipient embryos followed by electrofusion to reconstruct embryos. Fused couplets were cultured for 4 or 24 h before being transferred into day 1 pseudopregnant recipients (Hooded Wistar) at the 1- or 2-cell stage. In vitro culture was also carried out to check the developmental competence of the embryos. In vitro development to the blastocyst stage was not significantly different between the two groups (NT1, 34.3%; NT2, 45.0%). Two of three recipients from NT1 and two of five recipients from NT2 became pregnant. Six pups (3 from NT1, 3 from NT2) were delivered from the four foster mothers. Three female pups survived; 2 from NT1 and 1 from NT2. At 2 months of age these pups appeared healthy, and were mated with Sprague-Dawley males. One rat derived from NT1 delivered 15 pups (5 males, 10 females) as did the rat from NT2 (7 males, 8 females). Our results show that by using karyoplasts from 2-cell stage embryos as nuclear donors and reconstructing them with enucleated 2-cell embryos, healthy rats can be produced.     

In vitro oocyte culture and somatic cell nuclear transfer used to produce a live-born cloned goat

The use of an in vitro culture system was examined for production of somatic cells suitable for nuclear transfer in the goat. Goat cumulus-oocyte complexes were incubated in tissue culture medium TCM-199 supplemented with 10% fetal bovine serum (FBS) for 20 h. In vitro matured (IVM) oocytes were enucleated and used as karyoplast recipients. Donor cells obtained from the anterior pituitary of an adult male were introduced into the perivitelline space of enucleated IVM oocytes and fused by an electrical pulse. Reconstituted oocytes were cultured in chemically defined medium for 9 days. Two hundred and twenty-eight oocytes (70%) were fused with donor cells. After in vitro culture, seven somatic cell nuclear transfer (SCNT) oocytes (3%) developed to the blastocyst stage. SCNT embryos were transferred to the oviducts of recipient females (four 8-cell embryos per female) or uterine horn (two blastocysts per female). One male clone (NT1) was produced at day 153 from an SCNT blastocyst and died 16 days after birth. This study demonstrates that nuclear transferred goat oocytes produced using an in vitro culture system could develop to term and that donor anterior pituitary cells have the developmental potential to produce term offspring. In this study, it suggested that the artificial control of endocrine system in domestic animal might become possible by the genetic modification to anterior pituitary cells.     

Cloning of bovine embryos by multiple nuclear transfer

The in vitro development of multiple generation bovine nuclear transferred embryos to blastocysts and their survival ability after freezing and thawing were examined. Parent donor embryos which had 20 to 50 cells were recovered from superovulated cows. Follicular oocytes matured in vitro were used as recipient oocytes. The recipient oocytes enucleated at 22 to 24 h after the onset of maturation were preactivated at 33 h. Enucleated oocytes with a donor blastomere were fused 9 h after activation by an electric stimulus and the fused oocytes were cultured in vitro (first generation). Reconstituted oocytes that had developed to the 8- to 16-cell stage 3 to 4 d after fusion were used as donor embryos for the next generation. Recloning procedures were performed twice (second and third generations). The proportion of recipient oocytes successfully fused with a blastomere increased with the cycle of nuclear transfer. Eighty to 86% of fused oocytes developed to the 2-cell stage and there was no significant difference with the generation. The proportion of reconstituted embryos receiving blastomeres derived from first generation embryos had higher developmental ability in vitro, than those derived from other generations (43 vs 31% for 8 to 16-cell stage, 37 vs 20 and 21% for blastocyst stage). The number of cloned blastocysts increased with repeated nuclear transfer (once: 6.2 +/- 4.3, twice: 19.8 +/- 9.2 and three times: 30.0 +/- 14.7) but varied greatly with each parent donor embryo. The in vitro viability of cloned blastocysts after freezing and thawing (59%) was low but not significantly different from that obtained for in vitro fertilized blastocysts (72%). After transfer of either fresh or frozen-thawed cloned blastocysts to 21 recipients, 10 of them were pregnant on Day 60. Four and 3 offspring were produced from 20 fresh and 14 frozen-thawed blastocysts,respectively.     

Bovine oocytes vitrified by the open pulled straw method and used for somatic cell cloning supported development to term

The objective of the present study was to determine if oocytes vitrified by the open pulled straw (OPS) method could subsequently be used to produce somatic cell cloned cattle. Post-thaw survival rates were 77.0, 79.1, 97.2 and 97.5% for oocytes vitrified with EDFS30 (15% ethylene glycol, 15% dimethyl sulfoxide, ficoll and sucrose), EDFS40 (20% ethylene glycol, 20% dimethyl sulfoxide, ficoll and sucrose), EDFSF30 (15% ethylene glycol, 15% dimethyl sulfoxide, ficoll, sucrose and FBS) and EDFSF40 (20% ethylene glycol, 20% dimethyl sulfoxide, ficoll, sucrose and FBS), respectively. The parthenogenetic blastocyst rates of the vitrified-thawed oocytes activated with 5 microM of the calcium ionophore A23187 for 5 min and 2 microM of 6-dimethylaminopurin (6-DMAP) for 4h ranged from 10.3 to 23.0%, with the highest group not significantly differing from that of the controls (33.2%). In total, 722 vitrified-thawed oocytes were used as recipients for nuclear transfer, of which 343 fused (47.6%). Fifty-six (16.3%) of the reconstructed embryos reached the blastocyst stage after 7d of in vitro culture. Twenty-four blastocysts derived from vitrified-thawed oocytes were transferred to six Luxi yellow cattle recipients. Two recipients (33%) were diagnosed pregnant; one aborted 97 d after transfer, whereas the other delivered a cloned calf after 263 d. As a control, 28 synchronous Luxi yellow cattle recipients each received a single blastocyst produced using a fresh oocyte as a nuclear recipient; 10 recipients were diagnosed pregnant, of which 6 (21.4% of the original 28) delivered cloned calves. In conclusion, bovine oocytes vitrified by the OPS method and subsequently thawed supported development (to term) of somatic cell cloned embryos.     

Heterogeneous nuclear-transferred-embryos reconstructed with camel (Camelus bactrianus) skin fibroblasts and enucleated ovine oocytes and their development H-M

This study reconstructed heterogeneous embryos using camel skin fibroblast cells as donor karyoplasts and ovine oocytes as recipient cytoplasts for investigating the developmental potential of the reconstructed embryos. Serum-starved adult camel skin fibroblast cells were used as donor somatic cells. Ovine oocytes matured in vitro were employed as recipient cytoplasts. The fusion of fibroblast cells into recipient cytoplasm was induced by electrofusion. The fused oocytes were activated by 5mM/ml inomycin with 2mM/ml 6-dimethylaminopurine (6-DMAP). The activated reconstructed embryos were co-cultured with ovine cumulus cells in synthetic oviduct fluid supplemented with amino acid (SOFaa) and 10% fetal calf serum (FCS) for 168h. A total of 300 enucleated ovine oocytes were available for xenonuclear embryo reconstruction. The results showed that 71% of the nuclear transfer couplets were successfully fused, 55% of the fused oocytes cleaved within 48h after activation, 82% of the cleaved oocytes developed to 2-16-cell embryo stages and 18% of the cleaved nuclear transfer zygotes developed to the morula stage. This study demonstrated that the xenonuclear transfer camel embryos can undergo the first embryonic division and subsequent development to morula stage in vitro.     

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.