Production of nuclear transfer-derived swine that express the enhanced green fluorescent protein.

The ability to add or delete specific genes in swine will likely provide considerable benefits not just to agriculture but also to medicine, where pigs have potential as models for human disease and as organ donors. Here we have transferred nuclei from a genetically modified fibroblast cell line to porcine oocytes, matured in vitro under defined culture conditions, to create piglets expressing enhanced green fluorescent protein. The nuclear transfer-derived piglets were of normal size, although some mild symptoms of "large offspring syndrome" were evident. These experiments represent a next step towards creating swine with more useful genetic modifications.     

Production of transgenic cloned piglets from genetically transformed fetal fibroblasts selected by green fluorescent protein

This study was performed to develop a system for porcine somatic cell nuclear transfer (SCNT) and to produce human erythropoietin (hEPO)-transgenic cloned piglets. Porcine fetal fibroblasts were transfected with an expression plasmid (phEPO-GFP). In Experiment 1, the effect of transfection of phEPO-GFP transgene on development of porcine SCNT embryos was investigated. Three fetal fibroblast cell lines (two male and one female) with or without transfected with phEPO-GFP trasngene were used as donor cells for SCNT. Lower fusion rates were observed in two lines of transfected cells as compared to those of the control cells. In Experiment 2, the effect was examined of elevated Ca2+ concentration in the fusion/activation medium on development of transfected SCNT embryos. The rates of fusion and blastocyst formation were significantly increased by supplementing 1.0 mM of CaCl2 (versus 0.1 mM) into the fusion/activation medium. In Experiment 3, the effect was studied of a chemical treatment (cytochalasin B) after electric fusion/activation (F/A) on porcine transgenic SCNT embryo development. The electric F/A + cytochalasin B treatment increased total cell number in blastocysts as compared to that of electric F/A treatment alone. In Experiment 4, transgenic cloned embryos were transferred to surrogate mothers and a total of six cloned piglets were born. Transgenic cloned piglets were confirmed by polymerase chain reaction and Southern blot analysis. From a single surrogate mother, female and male transgenic cloned piglets were produced by transferring pooled SCNT embryos derived from female and male transfected donor cells. In conclusion, a system for porcine SCNT was developed and led to the successful production of hEPO transgenic cloned piglets.     

Expression of enhanced green fluorescent protein (EGFP) and neomycin resistant (Neo(R)) genes in porcine embryos following nuclear transfer with porcine fetal fibroblasts transfected by retrovirus vector

In this study, we demonstrated expression of enhanced green fluorescent protein (EGFP) and neomycin resistant (Neo(R)) genes in porcine embryos following nuclear transfer from porcine fetal fibroblasts (PFFs) transduced with the EGFP and Neo(R) genes by retrovirus-mediated infection. Nuclear transfer of the nonstarved transfected PFF into enucleated oocytes was accomplished by cell to cell fusion. Out of 188 porcine eggs reconstructed by nuclear transfer, 116 (61.7%) eggs cleaved and 25 (13.3%) developed to morula and blastocyst stages. Of these 25 morulae and blastocysts, 25 (100%) embryos emitted green fluorescence. Expression of the both EGFP and Neo(R) genes was detected as early as the 2-cell stage. As determined by EGFP gene expression, mosaicism was not observed in any embryo. These results suggest that porcine oocytes reconstructed by nuclear transfer with transfected PFFs can successfully develop to the blastocyst stage. In addition, this approach might be applicable to the production of transgenic pigs with complex genetic modifications.     

Transgenic pig expressing the enhanced green fluorescent protein produced by nuclear transfer using colchicine-treated fibroblasts as donor cells

Fetal-derived fibroblast cells were transduced with replication defective vectors containing the enhanced green fluorescent protein (EGFP). The transgenic cells were treated with colchicine, which theoretically would synchronize the cells into G2/M stage, and then used as donor nuclei for nuclear transfer. The donor cells were transferred into the perivitalline space of enucleated in vitro matured porcine oocytes, and fused and activated with electrical pulses. A total of 8.3% and 28.6% of reconstructed oocytes showed nuclear envelope breakdown and premature chromosome condensation 0.5 and 2 hr after activation, respectively. Percentage of pronuclear formation was 62.5, 12 hr after activation. Most (91.4%) of the 1-cell embryos with pronuclei did not extrude a polar body. Most (77.2%) embryos on day 5 were diploid. Within 2 hr after fusion, strong fluorescence was detectable in most reconstructed oocytes (92.3%). The fluorescence in all NT embryos became weak 15 hr after fusion and disappeared when culture to 48 hr. But from day 3, cleaved embryos at the 2- to 4-cell stage started to express EGFP again. On day 7, 85.8% of cleaved embryos expressed EGFP. A total of 9.4% of reconstructed embryos developed to blastocyst stage and 71.5% of the blastoctysts expressed EGFP. After 200 reconstructed 1-cell stage embryos were transferred into four surrogate gilts, three recipients were found to be pregnant. One of them maintained to term and delivered a healthy transgenic piglet expressing EGFP. Our data suggest that the combination of transduction of somatic cells by a replication defective vector with the nuclear transfer of colchicine-treated donors is an alternative to produce transgenic pigs. Furthermore, the tissues expressing EGFP from descendents of this pig may be very useful in future studies using pigs that require genetically marked cells.     

Expression of enhanced green fluorescent protein in porcine- and bovine-cloned embryos following interspecies somatic cell nuclear transfer of fibroblasts transfected by retrovirus vector

Interspecies somatic cell nuclear transfer (iSCNT) has emerged as an important tool for studying nucleo-cytoplasmic interactions and cloning of animals whose oocytes are difficult to obtain. This study was designed to explore the feasibility of employing transgenic fibroblasts as donor cells for iSCNT. The study examined the chromatin morphology, in vitro development, and expression of an enhanced green fluorescent protein (EGFP) gene in porcine- and bovine-cloned embryos produced by iSCNT of fetal fibroblast transfected with a pLNbeta-EGFP retroviral vector. Parthenogenetic and transfected or nontransfected intraspecies SCNT embryos were used as controls for comparison. Analysis of data revealed that xenogenic oocyte was able to reprogram somatic cells of different genus and supports their in vitro development to the blastocyst stage. However, the developmental rates of transgenic iSCNT embryos to the blastocyst stage were significantly lower than those of intraspecies SCNT embryos. The reduction in development rates was however, not due to integration of the transgene as the lower (P < 0.05) development rates of the intraspecies SCNT porcine or bovine embryos did not differ between transgenic and nontransgenic groups. Expression of EGFP was observed in 100% of blastocysts and mosaicism was not observed. Furthermore, after iSCNT of porcine or bovine donor nuclei into xenogenic ooplasm, patterns of nuclear remodeling in reconstructed embryos were similar. In conclusion, our data demonstrated the feasibility of producing transgenic iSCNT embryos. To our knowledge, this is the first report of transgenic cloned embryo production by iSCNT approach. In the future, this may provide a powerful research tool for studying developmental events in domestic animals and provide marked cell lines for other genetic manipulations.     

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 (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

Somatic cell nuclear transfer (SCNT), combined with genome modification techniques, is a very pow-erful tool for agriculture, medicine and fundamental research on basic biological mechanisms. The effi-ciency of producing transgenic animals is greatly prom…     

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.     

Establishment of porcine transgenic embryonic germ cell lines expressing enhanced green fluorescent protein

The purpose of this study was to isolate porcine embryonic germ (EG) cells and establish transgenic EG cell lines. Plasmid DNA was the enhanced green fluorescent protein (EGFP) vector. Porcine EG cells in rapid proliferation (4th to 9th passage) were transfected with LipofecTamine 2000 and TransFast reagents. Porcine EG cells transfected with a complex of 1 microg of DNA and 2 microL of LipofecTamine 2000 reagent yielded four EG-EGFP cell lines, which emitted bright green fluorescence. EG-EGFP cells cultured for more than 2 weeks without passage gave rise to various differentiated phenotypes. In addition, to determine the degree to which EG cells become integrated into the inner cell mass of host embryos, 135 embryos were injected with porcine EG-EGFP cells; 110 embryos survived and developed into blastocysts (81.5%). Eighty-four chimeric embryos contained fluorescent cells after culture; 49 blastocysts contained EG-EGFP cells in the inner cell mass. Our results suggested that the chimeric rate would not be improved via using different stages of embryos for injection.     

Examining the mechanism of Erk nuclear translocation using green fluorescent protein

In neuronal cells, the mitogen-activated protein kinase (MAP kinase) cascade is an important mediator of neurotrophin signaling from cell surface receptors to the nucleus, resulting in changes in gene expression. Nuclear localization of Erk is thought to be required for these effects. To examine the mechanism and regulation of Erk nuclear translocation, we have created a green fluorescent protein (GFP)-labeled Erk2 construct, which provides a sensitive means to follow the movement of Erk from the cytoplasm to the nucleus following receptor-mediated MAP kinase activation. Using this system in PC12 cells, we have examined a number of mechanisms that have been implicated in regulating the translocation of Erk. In PC12 cells, NGF and EGF induce a rapid translocation of GFP-Erk that requires Ras and Mek. We have found that prolonged phosphorylation of Erk is not required for the rapid and early influx of Erk into the nucleus following growth factor stimulation. Furthermore, following influx, GFP-Erk rapidly returned to the cytoplasm regardless of its phosphorylation state. The release of Erk from its cytoplasmic activator, Mek, followed by the dimerization of Erk, was sufficient to stimulate nuclear uptake, whereas Erk kinase activity was dispensable. PKA activity has been reported to be required for Erk translocation in PC12 cells. However, PKA activity was also not necessary for the early translocation of Erk into the nucleus by NGF or Ras, but it was able to induce a small influx of Erk that could be measured with GFP-Erk2.     

Developmental potential of porcine nuclear transfer embryos derived from transgenic fetal fibroblasts infected with the gene for the green fluorescent protein: comparison of different fusion/activation conditions.

The in vitro developmental potential of porcine nuclear transfer (NT) embryos was evaluated. Oocytes were matured for 42-44 h, and metaphase II-oocytes were enucleated. Fetal fibroblasts infected with the enhanced green fluorescent protein (EGFP) gene were serum-starved for 3-5 days. A single cell was injected into the perivitelline space of the enucleated oocytes. The reconstructed oocytes were allocated to different fusion and activation conditions. In experiment 1, two different fusion/activation conditions were compared: two pulses of 1.2 kV/cm for 30 microsec (group A), or one pulse of 1.6 kV/cm for 30 microsec followed in 30 min by one pulse of 1.2 kV/cm for 30 microsec (group B). Parthenogenetic controls were created by using the group A parameter. The fusion rate in group A (mean +/- SEM, 68.4% +/- 3.9%) was higher (P < 0.05) than in group B (59.4% +/- 2.3%). The rates of cleavage (50.1% +/- 4.6% to 62.8% +/- 5.5%) were not different among control and treatment groups. However, the rate of parthenogenetic control embryos developing to the blastocyst stage (18.1% +/- 3.1%) was higher (P < 0.05) than the rate of NT embryos (5.9% +/- 1.7% and 4.9% +/- 2.5%). In experiment 2, we compared two pulses of 1.2 kV/cm (group C) versus two pulses of 1.3 kV/cm (group D). For two control groups, the same pulses as those given to group C or D, respectively, were supplied. The fusion rate in group D (70.6% +/- 4.2%) was higher (P < 0.05) than in group C (58.9% +/- 2.7%). The cleavage rates were not different among control and treatment groups (58.1% +/- 8.1% to 73.6% +/- 6.0%). However, the rate of embryos developing to the blastocyst stage in group D (3.5% +/- 1.7%) was lower (P < 0.05) than in controls and group C (11.4% +/- 2.0% to 16.4% +/- 1.1%). In experiment 3, we examined whether the presence of cytochalasin B (CB) during donor cell injection affects the development of NT embryos. The fusion rate of oocytes in the group with CB (78.4% +/- 1.4%) was higher (P < 0.05) than in the group without CB (70.9% +/- 0.2%). The cleavage rate of the control group (85.5% +/- 4.9%) was higher (P < 0.05) than those of the treatment groups (61.6% +/- 2.7% and 63.9% +/- 4.3%). However, the rates of embryos developing to the blastocyst stage (8.1% +/- 2.5% to 19.1% +/- 6.0%) and the mean cell number of blastocysts (29.4 +/- 5.2 to 45.7 +/- 6.4) were not different among control and treatment groups. Green fluorescence was observed at all stages in NT embryos. These results indicate that two pulses of 1.2 kV/cm are enough for fusion/activation of NT embryos to develop to the blastocyst stage, and that the presence of CB during donor cell injection is not necessary for early development of NT embryos.     

In vitro development of porcine nuclear transfer embryos constructed using fetal fibroblasts

The in vitro development of porcine nuclear transfer embryos constructed using primary cultures from day 25 fetal fibroblasts which were either rapidly dividing (cycling) or had their cell-cycle synchronized in G0/G1 using serum starvation (serum-starved) was examined. Oocyte-karyoplast complexes were fused and activated simultaneously and then cultured in vitro for seven days to assess development. Fusion rates were not different for either cell population. The proportion of reconstructed embryos that cleaved was higher in the cycling group compared to the serum-starved group (79 vs. 56% respectively; P < 0.05). Development to the 4-cell stage was not different using either population. Both treatments supported similar rates of development to the morula (1.5 vs. 7%, cycling vs. serum-starved) and blastocyst stage (1.5 vs. 3%, cycling vs. serum-starved). The blastocyst produced using cycling cells had a total cell number of 10. Total cell numbers for the three blastocysts produced serum-starved cells were 22, 24, and 33. These blastocysts had inner cell mass numbers of 0, 15, and 4, respectively. Six hundred and thirty-five nuclear transfer embryos reconstructed using serum-starved cells were transferred to 15 temporarily mated recipients for 3-4 days. Of these, 486 were recovered (77% recovery rate) of which 106 (22%) had developed to the 4-cell stage or later. These were transferred to a total of 15 recipients which were either unmated or mated. Seven recipients farrowed a total of 51 piglets. Microsatellite analysis revealed that none of these were derived from the nuclear transfer embryos transferred.     

Production of transgenic recloned piglets harboring the human granulocyte-macrophage colony stimulating factor (hGM-CSF) gene from porcine fetal fibroblasts by nuclear transfer

We used nuclear transfer (NT) to develop transgenic female pigs harboring goat beta-casein promoter/human granulocyte-macrophage colony stimulating factor (hGM-CSF). The expression of hGM-CSF was specific to the mammary gland, and the glycosylation-derived size heterogeneity corresponded to that of the native human protein. Although various cell types have been used to generate cloned animals, little is currently known about the potential use of fibroblasts derived from a cloned fetus as donor cells for nuclear transfer. The developmental potential of porcine cloned fetal fibroblasts transfected with hGM-CSF was evaluated in the present study. Cloned fetal fibroblasts were isolated from a recipient following the transplantation of NT embryos. The cells were transfected with both hGM-CSF and the neomycin resistance gene in order to be used as donor cells for NT. Reconstructed embryos were implanted into six sows during estrus; two of the recipient sows delivered seven healthy female piglets with the hGM-CSF gene (confirmed with PCR and fluorescent in situ hybridization) and microsatellite analysis confirmed that the clones were genetically identical to the donor cells. The expression of hGM-CSF was strong in the mammary glands of a transgenic pig that died a few days prior to parturition (110 d after AI). These results demonstrated that somatic cells derived from a cloned fetus can be used to produce recloned and transgenic pigs.     

Production of transgenic recloned piglets harboring the human granulocyte-macrophage colony stimulating factor (hGM-CSF) gene from porcine fetal fibroblasts by nuclear transfer

We used nuclear transfer (NT) to develop transgenic female pigs harboring goat beta-casein promoter/human granulocyte-macrophage colony stimulating factor (hGM-CSF). The expression of hGM-CSF was specific to the mammary gland, and the glycosylation-derived size heterogeneity corresponded to that of the native human protein. Although various cell types have been used to generate cloned animals, little is currently known about the potential use of fibroblasts derived from a cloned fetus as donor cells for nuclear transfer. The developmental potential of porcine cloned fetal fibroblasts transfected with hGM-CSF was evaluated in the present study. Cloned fetal fibroblasts were isolated from a recipient following the transplantation of NT embryos. The cells were transfected with both hGM-CSF and the neomycin resistance gene in order to be used as donor cells for NT. Reconstructed embryos were implanted into six sows during estrus; two of the recipient sows delivered seven healthy female piglets with the hGM-CSF gene (confirmed with PCR and fluorescent in situ hybridization) and microsatellite analysis confirmed that the clones were genetically identical to the donor cells. The expression of hGM-CSF was strong in the mammary glands of a transgenic pig that died a few days prior to parturition (110 d after AI). These results demonstrated that somatic cells derived from a cloned fetus can be used to produce recloned and transgenic pigs.     

A highly sensitive assay for proteases using staphylococcal protein A fused with enhanced green fluorescent protein

Enhanced green fluorescent protein (EGFP) was fused with staphylococcal protein A (SpA) and used as a substrate for proteases. An SpA-EGFP assay was done in three steps: (i) digestion of SpA-EGFP by proteases, (ii) addition of rabbit IgG immobilized on Sepharose beads, and (iii) measurement of the fluorescence intensity of supernatant. The assay was sensitive enough to measure picogram levels of trypsin and chymotrypsin, and may be applicable to various other proteases as one of the most sensitive methods.     

Nuclear localization of enhanced green fluorescent protein homomultimers

The green fluorescent protein (GFP) and its variants are used in many studies to determine the subcellular localization of other proteins by analyzing fusion proteins. The main problem for nuclear localization studies is the fact that, to some extent, GFP translocates to the nucleus on its own. Because the nuclear import could be due to unspecific diffusion of the relatively small GFP through the nuclear pores, we analyzed the localization of multimers of a GFP variant, the enhanced GFP (EGFP). By detecting the fluorescence of the expressed proteins in gels after nonreducing SDS-PAGE, we demonstrate the integrity of the expressed proteins. Nevertheless, even EGFP homotetramers and homohexamers are found in the nuclei of the five analyzed mammalian cell lines. The use of fusion constructs of small proteins with multimeric EGFP alone, therefore, is not adequate to prove nuclear import processes. Fusion to tetrameric EGFP in combination with a careful quantification of the fluorescence intensities in the nucleus and cytoplasm might be sufficient in many cases to identify a significant difference between the fusion protein and tetrameric EGFP alone to deduce a nuclear localization signal.     

体细胞核移植生产绵羊转hALR基因囊胚

扩增人肝细胞再生增强因子(human augmenter of liver regeneration,ALR)基因,利用质粒pIRES2-EGFP 构建新霉素(Neo)、增强绿色荧光蛋白(enhanced green fluorescence protein,EGFP)双标记基因且EGFP和ALR基因为双顺反子的真核表达载体.LipofectAMINETM介导其转染体外培养的绵羊胎儿成纤维细胞(sheep fetal fibroblast cells,sFFCs);经G418筛选转基因细胞;激光共聚焦显微镜挑选绿色荧光单克隆细胞.PCR、RT-PCR和免疫组织化学方法进一步检测ALR基因及其表达;稳定表达外源基因的sFFCs作供体,移入去核的绵羊卵母细胞中,进行体细胞核移植.通过激光共聚焦显微镜和ALR抗体检测EGFP、ALR基因在胚胎水平上的表达,其结果表明:由IRES连接的EGFP和ALR基因可在绵羊胎儿成纤维细胞内同时表达,由此细胞核移植产生的转基因胚胎在发育的各阶段均可见绿色荧光;囊胚中所有细胞表达EGFP基因;发绿色荧光的胚胎中ALR基因同时存在.因此,由IRES连接标记基因和目的基因,以标记基因指示目的基因的表达,可简化检测目的基因的繁琐手段;用筛选的转基因早期胚胎进行移植,可提高制备转基因动物的效率.     

Production of transgenic embryos through nuclear transfer using ovine fetal fibroblasts transferred with foreign genes

Human ALR gene sequence was amplified by PCR from human total DNA and inserted into pIRES(2)-EGFP vector. The bicistronic eukaryotic expression vector, pIRES-EGFP/ALR, expressing EGFP, Neo(r) and ALR genes was constructed. Sheep fetal fibroblast cells (sEFCs) were transfected with pIRES-EGFP/ALR by the induction of lipofectAMINE(TM). The positive cell clones were selected with medium containing G418 (800 μg/mL). The fluorescence of transgenic cells was examined with a confocal laser scanning microscope. The expression of ALR gene was tested by PCR, RT-PCR and immuno-histochemical staining. The transgenic cells were used as donors for nuclear transfer to enucleated ovine oocytes. Transgenic embryos were tested by confocal laser scanning microscope and immuno-histochemical staining. Results showed that the EGFP and ALR genes linked with IRES were coexpressed simultaneously in sFFCs; the blastocysts formed by nuclear transfer using tranfected donor cells are all transgenic blastocysts. EGFP, ALR and Neo(r) gene were all expressed in the transgenic embryos. In conclusion that a method to construct the positive embryos before pre-implantation which stably express ALR gene by the indication of EGFP expression has been successfully established. The application of this method can simplify the procedure of testing the targets and contribute to the efficiency increasing of transgenic domestic animal production.     

Transgene expression of enhanced green fluorescent protein in cloned rabbits generated from in vitro-transfected adult fibroblasts

Live rabbits have previously been generated through nuclear transfer using adult cells as nuclear donors. We demonstrated in this study that transfected adult rabbit fibroblasts are also capable of supporting full-term development. The fibroblasts were transfected with a pEGFP-C1 plasmid using lipofectamine^™ 2000, and the transgenic cells were derived from conditioned medium. The transgenic fibroblasts were cultured until confluent and then serum-starved prior to be used as nuclear donors. After nuclear transfer and activation, 22% (12/55) of the transgenic cloned embryos developed to the blastocyst stage. A total of 114 embryos at the 4- to 8-cell stage were transferred to the oviducts of 8 pseudo-pregnant mothers; 5 of these animals became pregnant, and 3 of the 5 mother rabbits carried the pregnancy to term. Caesarean section was performed on the 3 pregnant mothers, yielding 4 kits, one of which has survived for more than 9 months. Green fluorescence could be detected in the toenails of the living cloned rabbit and the offspring from the living cloned rabbit under ultraviolet light. DNA analyses confirmed that all 4 cloned rabbits were genetically identical to the transgenic donor cells, and that they all carried the EGFP gene. The present study demonstrated that transgenic rabbits can be generated through nuclear transfer. These results may facilitate future developments in the genetic engineering of rabbits.