Production and health assessment of second-generation cloned Holstein cows derived by somatic cell nuclear transfer

In this study we evaluated cloning efficiency of second-generation (G2) cloned Holstein cows derived from ear fibroblasts of a first-generation (G1) cloned cow, and assessed their health status in terms of physical, growth and reproductive parameters. Compared with G1 cloning, G2 cloning showed a slight decrease on blastocyst rate of reconstructed embryos (30.2±5.8% vs. 28.5±7.2%, p>0.05), while the quality of its blastocysts reduced significantly (Grade 1 and Grade 2, 21.1±4.1% vs. 17.1±5.7%, p<0.05). After embryo transfer (ET), both pregnancy rate to term and calving rate of G2 cloning were approximately half of G1 cloning (5.8% vs. 10.7%; 3.9% vs. 8.6%, p>0.05). Six G2 cloned cows were delivered, and three of them survived. G2 cloned calves displayed symptoms of being overweight at birth and tachycardia in the first week after birth. During the first 12 months, the growth of G2 cloned calves was similar to control calves derived from artificial insemination (AI). Furthermore, the interindividual variation of growth within the G2 clonal family was smaller except at birth and at two months of age. Interestingly, although G2 cloned cows reached puberty 45 days later in comparison with control cows derived from AI, they were all pregnant by AI, and gave birth to healthy calves. This suggests that their reproductive performance was not affected by late puberty. In summary, our results showed that although cloning efficiency of G2 was lower than that of G1, the surviving G2 clones appeared physically healthy and were fertile.     

Production of cloned mice by somatic cell nuclear transfer

Although it has now been 10 years since the first cloned mammals were generated from somatic cells using nuclear transfer (NT), the success rate for producing live offspring by cloning remains < 5%. Nevertheless, the techniques have potential as important tools for future research in basic biology. We have been able to develop a stable NT method in the mouse, in which donor nuclei are directly injected into the oocyte using a piezo-actuated micromanipulator. Although manipulation of the piezo unit is complex, once mastered it is of great help not only in NT experiments but also in almost all other forms of micromanipulation. In addition to this technique, embryonic stem (ES) cell lines established from somatic cell nuclei by NT can be generated relatively easily from a variety of mouse genotypes and cell types. Such NT-ES cells can be used not only for experimental models of human therapeutic cloning but also as a backup of the donor cell's genome. Our most recent protocols for mouse cloning, as described here, will allow the production of cloned mice in > or = 3 months.     

Reproductive fertility of cloned male cats derived from adult somatic cell nuclear transfer

This study was designed to investigate the reproductive fertility by the natural breeding of cloned male cats with domestic female cats, and to measure endocrine hormone concentration related to male reproduction such as testosterone, leutinizing hormone (LH), and follicle stimulating hormone (FSH). Cloned A, B, C, and D cats produced three, two, four, and five kittens after natural mating with four domestic female cats, respectively, despite later puberty of the cloned D cat than those of the other cloned male cats. Three of the 14 kittens expressed an odd eye color, which was produced by 1 and 2 from cloned A and B cats. The eye color of the other F1 kittens varied from nine brown to two blue. Body weight at birth ranged from 72.9 to 134.0 g. Although clone D had a poorer libido and entered puberty later than those of the other cloned male cats, he produced gonadal hormones within the average range. Four of the cloned male cats had normal fertility. The concentration of gonadal hormones in cloned male cats was similar to two control and donor cats. The concentration of testosterone was not significantly different among clones A, B, C, D, and control cats (5.99 +/- 5.68; 3.46 +/- 2.81; 6.41 +/- 2.17; 3.75 +/- 0.34; 4.0 +/- 3.63 ng/mL, p < 0.05). The concentrations of LH and FSH were not significantly different among the cloned cats (p < 0.05). Seven male and seven female (in total 14) kittens were produced by the natural breeding with four domestic female cats. These results indicated that cloned male cats have normal reproductive fertility and lie within the normal range of gonadal hormone production. All F1 kittens were produced by natural breeding and delivery, and are still alive and have normal growth health (27 months age).     

Production of porcine cloned transgenic embryos expressing green fluorescent protein by somatic cell nuclear transfer

In the present study, nuclear transferred embryos (NTEs) were reconstructed by using pig fetal fibroblasts as donors and in vitro matured oocytes as recipients. The effects of G418 selection on donor cells, duration of IVM of prepubertal gilt oocytes and oxygen tension in IVM of oocytes were investigated. The results were as follows: (i) When G418 selected cells expressing GFP were used as donors, the cleavage rate of NTEs decreased drastically in comparison to NTEs derived from donors without antibiotic selection (45.7% vs. 71.6%, p<0.05). For the blastocyst rate, no significant difference was observed between two groups (10% vs. 10.4%, p>0.05). (ii) The rate of nuclear maturation of oocytes increased significantly when IVM duration time was extended from 36h to 42h (83.6% vs. 96.7%, p<0.05). However, no statistical difference were observed between NTEs derived from oocytes of 36 h IVM group and NTEs from oocytes of 42 h IVM group in the rates of cleavage (59.3% vs. 73.6%, p>0.05) and blastocyst formation (9.3% vs. 13.2%, p>0.05); (iii) no significant difference was observed between NTEs reconstructed from oocytes matured under lower oxygen (7% O₂) tension and NTEs derived from oocytes matured under higher oxygen tension (20% O₂) in cleavage rate (70.6% vs. 67.1%, p>0.05) and blastocyst rate (11.8% vs. 12.8%, p>0.05). These results suggest that: (i) G418 selection does not have a significant effect on cleavage rate of NTEs expressing GFP. (ii) Nuclear maturation is greatly improved by prolonging IVM duration from 36 to 42 h, while no significant differences were observed for developmental potential of transgenic embryos. Thus IVM 42 h is the better choice in order to obtain maximum number of MII oocytes as recipients. (iii) Lower oxygen tension and higher oxygen tension in IVM have no significant effect on development of cloned embryos.     

Production of porcine cloned transgenic embryos expressing green fluorescent protein by somatic cell nuclear transfer

In the present study, nuclear transferred embryos (NTEs) were reconstructed by using pig fetal fibroblasts as donors and in vitro matured oocytes as recipients. The effects of G418 selection on donor cells, duration of IVM of prepubertal gilt oocytes and oxygen tension in IVM of oocytes were investigated. The results were as follows: (i) When G418 selected cells expressing GFP were used as donors, the cleavage rate of NTEs decreased drastically in comparison to NTEs derived from donors without antibiotic selection (47.5% vs. 71.6%, p<0.05). For the blastocyst rate, no significant difference was observed between two groups (10% vs. 10.4%, p>0.05). (ii) The rate of nuclear maturation of oocytes increased significantly when IVM duration time was extended from 36 to 42 h (83.6% vs. 96.7%, p<0.05). However, no statistical difference was observed between NTEs derived from oocytes of 36 h IVM group and NTEs from oocytes of 42 h IVM group in the rates of cleavage (59.3% vs. 73.6%, p>0.05) and blastocyst formation (9.3% vs. 13.2%, p>0.05); (iii) no significant difference was observed between NTEs reconstructed from oocytes matured under lower oxygen (7% O₂) tension and NTEs derived from oocytes matured under higher oxygen tension (20% O₂) in cleavage rate (70.6% vs. 67.1%, p>0.05) and blastocyst rate (11.8% vs. 12.3%, p>0.05). These results suggest that: (i) G418 selection does not have a significant effect on cleavage rate of NTEs expressing GFP. (ii) Nuclear maturation is greatly improved by prolonging IVM duration from 36 to 42 h, while no significant differences were observed for developmental potential of transgenic embryos. Thus IVM 42 h is the better choice in order to obtain maximum number of MII oocytes as recipients. (iii) Lower oxygen tension and higher oxygen tension in IVM have no significant effect on development of cloned embryos.     

Production of porcine cloned transgenic embryos expressing green fluorescent protein by somatic cell nuclear transfer

In the present study, nuclear transferred embryos (NTEs) were reconstructed by using pig fetal fibroblasts as donors and in vitro matured oocytes as recipients. The effects of G418 selection on donor cells, duration of IVM of prepubertal gilt oocytes and oxygen tension in IVM of oocytes were investigated. The results were as follows: (i) When G418 selected cells expressing GFP were used as donors, the cleavage rate of NTEs decreased drastically in comparison to NTEs derived from donors without antibiotic selection (45.7% vs. 71.6%, p<0.05). For the blastocyst rate, no significant difference was observed between two groups (10% vs. 10.4%, p>0.05). (ii) The rate of nuclear maturation of oocytes increased significantly when IVM duration time was extended from 36h to 42h (83.6% vs. 96.7%, p<0.05). However, no statistical difference were observed between NTEs derived from oocytes of 36 h IVM group and NTEs from oocytes of 42 h IVM group in the rates of cleavage (59.3% vs. 73.6%, p>0.05) and blastocyst formation (9.3% vs. 13.2%, p>0.05); (iii) no significant difference was observed between NTEs reconstructed from oocytes matured under lower oxygen (7% O₂) tension and NTEs derived from oocytes matured under higher oxygen tension (20% O₂) in cleavage rate (70.6% vs. 67.1%, p>0.05) and blastocyst rate (11.8% vs. 12.8%, p>0.05). These results suggest that: (i) G418 selection does not have a significant effect on cleavage rate of NTEs expressing GFP. (ii) Nuclear maturation is greatly improved by prolonging IVM duration from 36 to 42 h, while no significant differences were observed for developmental potential of transgenic embryos. Thus IVM 42 h is the better choice in order to obtain maximum number of MII oocytes as recipients. (iii) Lower oxygen tension and higher oxygen tension in IVM have no significant effect on development of cloned embryos.     

Production of goats by somatic cell nuclear transfer.

In this study, we demonstrate the production of transgenic goats by nuclear transfer of fetal somatic cells. Donor karyoplasts were obtained from a primary fetal somatic cell line derived from a 40-day transgenic female fetus produced by artificial insemination of a nontransgenic adult female with semen from a transgenic male. Live offspring were produced with two nuclear transfer procedures. In one protocol, oocytes at the arrested metaphase II stage were enucleated, electrofused with donor somatic cells, and simultaneously activated. In the second protocol, activated in vivo oocytes were enucleated at the telophase II stage, electrofused with donor somatic cells, and simultaneously activated a second time to induce genome reactivation. Three healthy identical female offspring were born. Genotypic analyses confirmed that all cloned offspring were derived from the donor cell line. Analysis of the milk of one of the transgenic cloned animals showed high-level production of human antithrombin III, similar to the parental transgenic line.     

Production of rhesus monkey cloned embryos expressing monomeric red fluorescent protein by interspecies somatic cell nuclear transfer

Interspecies somatic cell nuclear transfer (iSCNT) is a promising method to clone endangered animals from which oocytes are difficult to obtain. Monomeric red fluorescent protein 1 (mRFP1) is an excellent selection marker for transgenically modified cloned embryos during somatic cell nuclear transfer (SCNT). In this study, mRFP-expressing rhesus monkey cells or porcine cells were transferred into enucleated porcine oocytes to generate iSCNT and SCNT embryos, respectively. The development of these embryos was studied in vitro. The percentage of embryos that underwent cleavage did not significantly differ between iSCNT and SCNT embryos (P > 0.05; 71.53% vs. 80.30%). However, significantly fewer iSCNT embryos than SCNT embryos reached the blastocyst stage (2.04% vs. 10.19%, P < 0.05). Valproic acid was used in an attempt to increase the percentage of iSCNT embryos that developed to the blastocyst stage. However, the percentages of embryos that underwent cleavage and reached the blastocyst stage were similar between untreated iSCNT embryos and iSCNT embryos treated with 2 mM valproic acid for 24 h (72.12% vs. 70.83% and 2.67% vs. 2.35%, respectively). These data suggest that porcine-rhesus monkey interspecies embryos can be generated that efficiently express mRFP1. However, a significantly lower proportion of iSCNT embryos than SCNT embryos reach the blastocyst stage. Valproic acid does not increase the percentage of porcine-rhesus monkey iSCNT embryos that reach the blastocyst stage. The mechanisms underling nuclear reprogramming and epigenetic modifications in iSCNT need to be investigated further.     

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.     

Effective donor cell fusion conditions for production of cloned dogs by somatic cell nuclear transfer

As shown by the birth of the first cloned dog ‘Snuppy', a protocol to produce viable cloned dogs has been reported. In order to evaluate optimum fusion conditions for improving dog cloning efficiency, in vivo matured oocytes were reconstructed with adult somatic cells from a female Pekingese using different fusion conditions. Fusion with needle vs chamber methods, and with low vs high pulse strength was compared by evaluating fusion rate and in vivo development of canine cloned embryos. The fusion rates in the high voltage groups were significantly higher than in the low voltage groups regardless of fusion method (83.5 vs 66.1% for the needle fusion method, 67.4 vs 37.9% for the fusion chamber method). After embryo transfer, one each pregnancy was detected after using the needle fusion method with high and low voltage and in the chamber fusion method with high voltage, whereas no pregnancy was detected using the chamber method with low voltage. However, only the pregnancy from the needle fusion method with high voltage was maintained to term and one healthy puppy was delivered. The results of the present study demonstrated that two DC pulses of 3.8 to 4.0 kV/cm for 15 μsec using the needle fusion method were the most effective method for the production of cloned dogs under the conditions of this experiment.     

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

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

Semen characteristics of genetically identical male cats cloned via somatic cell nucleus transfer

We investigated the sperm characteristics of four cloned male cats (Felis catus) to assess their reproductive potential. Fresh and frozen-thawed sperm were assessed for motility, viability, and morphology, and their functional competence was evaluated by in vitro fertilization (IVF) of domestic cat oocytes. All fresh semen characteristics varied among cats and collection times. Sperm concentration (× 10⁶/mL) of Cat A (512 ± 140, range 368 to 685) was significantly higher, whereas that of Cat C (335 ± 92, range 274 to 469) was significantly lower than that of Cloned B (459 ± 159, range 336 to 510) and control cats (680 ± 452, range 360 to 479). After thawing, motility and progressive motility of sperm from Cat B were significantly lower than that of the other cloned and control cats. The curvilinear, straight line, and average path velocities of sperm from Cat B were significantly higher, whereas the straightness was lower, than that of the other cloned and control cats. Frozen sperm from Cats A, B, and C successfully fertilized oocytes (cleavage = 74.4%, 71.4%, and 86.2%, respectively) and produced embryos that developed to the blastocyst stage after IVF/In vitro culture (IVC) (34.4%, 26.7%, and 48.0%) at frequencies similar to the cleavage rate (82.0%) and blastocyst rate (43.9%) obtained with sperm from the control male. In conclusion, seminal characteristics of cloned male cats did not differ markedly from those of our noncloned, control male cats.     

Production GH transgenic goat improving mammogenesis by somatic cell nuclear transfer

Growth hormone is a positive regulator of mammary gland development. Dairy animals that are administered growth hormone display enhanced lactation performance, a desirable agricultural trait. The objective of the current research was to generate an improved milk production phenotype in a large animal model using over-expressed GH in the mammary gland to promote mammogenesis. To this end, we constructed a mammary gland-specific expression vector, pcGH, and demonstrated effective GH expression in goat mammary epithelial cells in vitro by ELISA. Then, to produce transgenic offspring that were capable of stable GH expression in vivo, the linearized pcGH vector was electroporated into goat fetal fibroblasts. Cell colonies that were positive for GH were used as donors for nuclear transfer to enucleated oocytes. A total of 253 morulae or blastocytes developed from the reconstructed embryos were transferred to 56 recipients, resulting in 24 pregnancies at day 35. Finally, six transgenic goats were born. PCR detection confirmed the success of the cloning procedure. To observe the mammogenesis of dairy goats, the GH transgenic goats were mated with a completely healthy buck. In the later pregnancy period, the mammary gland of the GH transgenic goats were extensive than non-transgenic goats. These experiments indicated that the pcGH vector was incorporated into the transgenic goats and affected mammogenesis, which laid a solid foundation for elucidating the impact of GH on mammogenesis and lactation performance.     

Buffalos (Bubalus bubalis) cloned by nuclear transfer of somatic cells

Cloning of buffalos (Bubalus bubalis) through nuclear transfer is a potential alternative approach in genetic improvement of buffalos. However, to our knowledge, cloned offspring of buffalos derived from embryonic, fetal, or somatic cells have not yet been reported. Thus, factors affecting the nuclear transfer of buffalo somatic cells were examined, and the possibility of cloning buffalos was explored in the present study. Treatment of buffalo fibroblasts and granulosa cells with aphidicolin plus serum starvation resulted in more cells being arrested at the G0/G1 phase, the proportion of cells with DNA fragmentation being less, and the number of embryos derived from these cells that developed to blastocysts being greater. In addition, a difference was found in the development of embryos reconstructed with fetal fibroblasts from different individuals (P < 0.001). Forty-two blastocysts derived from granulosa cells and fetal fibroblasts were transferred into 21 recipient swamp buffalos, and 4 recipients were confirmed to be pregnant by rectal palpation on Day 60 of gestation. One recipient received two embryos from fetal fibroblasts aborted on Day 300 of gestation and delivered two female premature calves. Three recipients maintained pregnancy to term and delivered three female cloned calves after Days 338-349 of gestation. These results indicate that buffalo embryos derived from either fetal fibroblasts or granulosa cells can develop to the term of gestation and result in newborn calves.     

Production of transgenic canine embryos using interspecies somatic cell nuclear transfer

Somatic cell nuclear transfer (SCNT) has emerged as an important tool for producing transgenic animals and deriving transgenic embryonic stem cells. The process of SCNT involves fusion of in vitro matured oocytes with somatic cells to make embryos that are transgenic when the nuclear donor somatic cells carry 'foreign' DNA and are clones when all the donor cells are genetically identical. However, in canines, it is difficult to obtain enough mature oocytes for successful SCNT due to the very low efficiency of in vitro oocyte maturation in this species that hinders canine transgenic cloning. One solution is to use oocytes from a different species or even a different genus, such as bovine oocytes, that can be matured easily in vitro. Accordingly, the aim of this study was: (1) to establish a canine fetal fibroblast line transfected with the green fluorescent protein (GFP) gene; and (2) to investigate in vitro embryonic development of canine cloned embryos derived from transgenic and non-transgenic cell lines using bovine in vitro matured oocytes. Canine fetal fibroblasts were transfected with constructs containing the GFP and puromycin resistance genes using FuGENE 6?. Viability levels of these cells were determined by the MTT [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide] assay. Interspecies SCNT (iSCNT) embryos from normal or transfected cells were produced and cultured in vitro. The MTT measurement of GFP-transfected fetal fibroblasts (mean OD = 0.25) was not significantly different from non-transfected fetal fibroblasts (mean OD = 0.35). There was no difference between transgenic iSCNT versus non-transgenic iSCNT embryos in terms of fusion rates (73.1% and 75.7%, respectively), cleavage rates (69.7% vs. 73.8%) and development to the 8-16-cell stage (40.1% vs. 42.7%). Embryos derived from the transfected cells completely expressed GFP at the 2-cell, 4-cell, and 8-16-cell stages without mosaicism. In summary, our results demonstrated that, following successful isolation of canine transgenic cells, iSCNT embryos developed to early pre-implantation stages in vitro, showing stable GFP expression. These canine-bovine iSCNT embryos can be used for further in vitro analysis of canine transgenic cells and will contribute to the production of various transgenic dogs for use as specific human disease models.     

Production of transgenic chimera rabbit fetuses using somatic cell nuclear transfer

We produced aggregate chimeric embryos between blastomeres from the somatic cell nuclear transfer (SCNT) embryos and blastomeres from normal embryos. The SCNT embryos were produced by fusing enucleated oocytes with GFP gene introduced fibroblast cells, which were derived from a day 16 fetus. GFP gene-introduced fibroblast cells were cultured and passaged four to 12 times over a period of 45-79 days before SCNT. After transferring them into pseudopregnant recipient rabbits, the 15-day postcoitus fetuses were collected. We examined the existence of the cells derived from SCNT embryos in the fetus stage of pregnancy to detect the GFP gene. Fetuses that were not collected continued to develop into newborn rabbits. Two hundred and thirty-six chimeric embryos were produced using 39 SCNT morula stage embryos, and these embryos were transferred to 11 recipient rabbits. As a result, 27 normally developed and 16 degenerated concepti were obtained. The GFP gene-positive signals were detected in one of the fetuses, two of the placentae, and two of the degenerated concepti. In this study, we found that the rabbit SCNT embryos have the ability to develop and differentiate in vivo. We also demonstrated a novel method of producing a transgenic rabbit using SCNT.     

Cloned ferrets produced by somatic cell nuclear transfer

Somatic cell nuclear transfer (SCNT) offers great potential for developing better animal models of human disease. The domestic ferret (Mustela putorius furo) is an ideal animal model for influenza infections and potentially other human respiratory diseases such as cystic fibrosis, where mouse models have failed to reproduce the human disease phenotype. Here, we report the successful production of live cloned, reproductively competent, ferrets using species-specific SCNT methodologies. Critical to developing a successful SCNT protocol for the ferret was the finding that hormonal treatment, normally used for superovulation, adversely affected the developmental potential of recipient oocytes. The onset of Oct4 expression was delayed and incomplete in parthenogenetically activated oocytes collected from hormone-treated females relative to oocytes collected from females naturally mated with vasectomized males. Stimulation induced by mating and in vitro oocyte maturation produced the optimal oocyte recipient for SCNT. Although nuclear injection and cell fusion produced mid-term fetuses at equivalent rates (approximately 3-4%), only cell fusion gave rise to healthy surviving clones. Single cell fusion rates and the efficiency of SCNT were also enhanced by placing two somatic cells into the perivitelline space. These species-specific modifications facilitated the birth of live, healthy, and fertile cloned ferrets. The development of microsatellite genotyping for domestic ferrets confirmed that ferret clones were genetically derived from their respective somatic cells and unrelated to their surrogate mother. With this technology, it is now feasible to begin generating genetically defined ferrets for studying transmissible and inherited human lung diseases. Cloning of the domestic ferret may also aid in recovery and conservation of the endangered black-footed ferret and European mink.     

Cloning non-HUMAN primates by somatic cell nuclear transfer

正The recent breakthrough in successful producing cloned nonhuman primates by somatic cell nuclear transfer(SCNT)has attracted great attention both scientifically and publically(Liu et al.,2018).Two macaque monkeys,named"Zhongzhong"and"Huahua",were cloned from fetal fi-