Effect of transfection and passage number of ear fibroblasts on in vitro development of bovine transgenic nuclear transfer embryos

The objective of this study was to determine if the transfection of human prourokinase (ProU) gene and passage number of transfected ear fibroblasts affected in vitro development of bovine transgenic nuclear transfer (NT) embryos. An expression plasmid for human ProU was constructed by inserting a bovine beta-casein promoter, a green fluorescent protein (GFP) marker and human ProU gene into a pcDNA3 plasmid and transfected into bovine ear fibroblasts using a lipid mediated method. Abattoir derived oocytes were enucleated at 18-20 hr post maturation and a single donor cell was transferred into the perivitelline space of a recipient oocyte. After fusion and activation, the couplets were cultured in modified synthetic oviductal fluid (mSOF) medium for 168 hr. In Experiment 1, significantly lower rate in blastocysts formation (10.3%) was observed in transfected donor cells at early passage than that in nontransfected counterparts (22.1%, P<0.05). In Experiment 2, development to blastocysts and GFP expression in blastocysts were not significantly different between early (3-7) and late (8-12) passage donor cells (10.3 vs. 11.3% and 54.5 vs. 41.7%, respectively). This study indicates that in vitro development of bovine transgenic NT embryos is negatively influenced by transfection of human ProU gene into donor fibroblasts. However, passage number of transfected ear fibroblasts does not affect in vitro development of bovine transgenic NT embryos.     

Selection of donor nuclei in somatic cell-mediated gene transfer using a co-transfection method

In this study, we introduced a co-transfection method for the selection of donor nuclei in somatic cell-mediated nuclear transfer. Two vectors were constructed in our experiment. One was pMSCV-GFP carrying the neomycin-resistant gene (Neo(r)) and the green fluorescent protein (GFP) reporter gene; the other was pBC1-GFP carrying the mammary gland-specific promoter and target gene GFP. Ovine adult fibroblasts were co-transfected with pMSCV-GFP and pBC1-GFP. The data from this work demonstrated that the GFP genes in both vectors could successfully co-integrate into the genomes of ovine adult fibroblasts in three of the four transgenic cell clones assayed. Furthermore, PCR analysis of transgenic embryos proved that the GFP genes in both vectors could co-integrate into the genomes of the reconstructed embryos. Subsequently, analysis of the developmental rate of the reconstructed embryos after nuclear transfer indicated that the blastocyst rate from the co-transfected donor cells was similar (approximate 8 percent) to that from individual pMSCV-GFP transfected donor cells. The influence of co-transfection resulting in modification of donor nuclei on development of reconstructed embryos was also investigated. The results of flow cytometric analysis indicated that the co-transfected ovine fibroblasts had similar quiescent characteristics in terms of cell cycle (G0+G1 percent: 73.20 +/- 4.04) to the individual pMSCV-GFP transfected fibroblasts (G0+G1 percent: 70.77 +/- 1.19) after they were treated with serum starvation for five days. Our results suggest that the co-transfection method can be used for selection of donor cell clones in somatic cell-mediated gene transfer experiments. It can be potentially extended to applications related to expression of functional protein in mammary glands and other transgenic research relevant to nuclear transfer.     

Development potential of transgenic somatic cell nuclear transfer embryos according to various factors of donor cell

The present study was conducted to establish an efficient production system for bovine transgenic somatic cell nuclear transfer (SCNT) embryos, the effect of various conditions of donor cells including cell type, size, and passage number on the developmental competence of transgenic SCNT embryos were examined with their expression rates of a marker gene. An expression plasmid for human prourokinase was constructed by inserting a bovine beta-casein promoter, a green fluorescent protein (GFP) marker gene, and a human prourokinase target gene into a pcDNA3 plasmid. Three types of bovine somatic cells including two adult cells (cumulus cells and ear fibroblasts) and fetal fibroblasts were prepared and transfected with the expression plasmid using a liposomal transfection reagent, Fugene6, as a carrier. In Experiment 1, three types of bovine cells were transfected at passages 2 to 4, and then trypsinized and GFP-expressing cells were randomly selected and used for SCNT. Developmental competence and rates of GFP expression in bovine transgenic SCNT embryos reconstructed with cumulus cells were significantly higher than those from fetal and ear fibroblasts. In all cell types used, GFP expression rates of SCNT embryos gradually decreased with the progression of embryo development. In Experiment 2, the effect of passage number of cumulus cells in early (2 to 4) and late (8 to 12) passages was investigated. No significant differences in the development of transgenic SCNT embryos were observed, but significantly higher GFP expression was shown in blastocysts reconstructed with cumulus cells at early passage. In Experiment 3, different sizes of GFP-expressing transfected cumulus cells [large (>30 microm) or small cell (<30 microm)] at passages 2 to 4 were used for SCNT. A significant improvement in embryo development and GFP expression was observed when small cumulus cells were used for SCNT. Taken together, these results demonstrate that (1) adult somatic cells as well as fetal cells could serve as donor cells in transgenic SCNT embryo production and cumulus cells with small size at early passage were the optimal cell type, and (2) transgenic SCNT embryos derived from adult somatic cells have embryonic development potential.     

转GFP基因核移植牛胚胎的研究

试验采用脂质体转染法与电穿孔法,以携带绿色荧光蛋白（GFP）-新霉抗性（neo-）双标记基因的pMSCV质粒转染胎牛耳成纤维细胞为供体与体外成熟的牛卵母细胞为受体构建克隆胚。研究了体外成熟培养液中添加EGF（表皮生长因子）对转基因胚的影响,不同转染方法构建供体细胞对重构胚发育的影响和在不同体外培养系统中的发育效果。结果显示,体外成熟培养液中添加EGF 30 ng/mL组的卵母细胞成熟率最高,但对后期转基因重构胚的囊胚发育率的影响,以添加EGF 20 ng/mL组的最高;以胎牛耳成纤维细胞为供体细胞,不同转染方法转染供体细胞构建重构胚,其囊胚发育率差异不显著（P>〖JP2〗0.05）;mSOFaa+颗粒细胞单层细胞共培养体系中的转基因囊胚发育率最好,该体系更适合体细胞核移植法生产转基因牛胚胎。     

Effect of Transgene Introduction and Recloning on Efficiency of Porcine Transgenic Cloned Embryo Production In Vitro

Retrovirus-mediated exogenous gene transfection of somatic cells is an efficient method to produce transgenic embryos by somatic cell nuclear transfer (SCNT). This study evaluated whether efficiency of transgenic embryos production, by SCNT using fibroblast cells transfected by retrovirus vector, is influenced by the introduced transgene and whether recloning could further improve its efficiency. Transgenic cloned embryos were produced by SCNT of porcine foetal fibroblast cells transfected by either LNβ-Z or LNβ-enhanced green fluorescent protein (EGFP) retrovirus vector and evaluated for their developmental ability in vitro . Blastomeres from four-cell stage porcine embryos, produced by SCNT of foetal fibroblast cells transfected with LNβ-EGFP retroviral vector, were subsequently recloned into enucleated metaphase II oocytes and evaluated for changes in chromatin configuration, in vitro embryo development and gene expression. Analysis of results showed that cleavage and blastocyst rates of porcine SCNT embryos, using LacZ (53.6 ± 6.4%; 12.0 ± 5.7%) or EGFP (57.5 ± 6.3%; 10.1 ± 4.1%) transfected fibroblasts, did not differ (p > 0.05) from those of non-transfected controls (60.9 ± 8.2%; 12.3 ± 4.0%). Recloning of blastomeres did not further improve the in vitro development rate. Interestingly, the nuclei of blastomere underwent slower remodelling process than somatic cell nuclei. Both cloned and recloned embryos showed 100% transgene expression and there were no evidence of mosaicism. In conclusion, our data shows that the efficiency of transgenic cloned embryos production by SCNT of somatic cells transfected with replication-defective retrovirus vector is not influenced by the transgene introduction into donor cells and recloning of four-cell stage blastomere could not further improve its efficiency.     

Generation of Buffalo (Bubalus bubalis) Transgenic Chimeric and Nuclear Transfer Embryos Using Embryonic Germ-Like Cells Expressing Enhanced Green Fluorescent Protein

The possibility of producing transgenic buffalo embryos by chimera and nuclear transfer (NT) using buffalo embryonic germ (EG)‐like cells expressing enhanced green fluorescent protein (EGFP) has been explored in this study. Buffalo EG‐like cells and fibroblasts with two to eight passages were transfected with the lined plasmid (pCE‐EGFP‐IRES‐Neo‐dNdB) using Lipofectamine^TM 2000 and selected by culturing in 200 μg/ml G418 for 6–8 days. G418 resistant fibroblasts and EG‐like cells were used for embryo chimera and NT. To produce blastocysts by chimera, 8–16 cells embryos were injected with EG‐like and fibroblast cells. Then, to produce blastocysts by NT, in vitro maturated oocytes were enucleated and afterwards EG‐like/fibroblast cells transferred into the perivitelline space. No statistical differences were observed for the total blastocyst produced by the chimeric method, using EG‐like and fibroblasts as donor cells, resulting on an accomplishment of 35.6% vs 33.3%, respectively. Nevertheless, besides from the 37 blastocysts produced, 23 (62.2%) from EG‐like cells expressed EGFP, none of blastocysts from foetal fibroblasts expressed this protein. When the NT method was used, no statistical difference among different generations was observed in the percentage of oocytes fused, cleaved, and developed to blastocysts after NT for EG‐like cells. On average, the percentage of oocytes fused, cleaved, and developed to blastocysts after NT was respectively 81.8%, 67.7% and 10.7%. For the expression of EGFP, from the 12 blastocysts produced by NT, 7 of them were positive, while none of NT embryos from EGFP positive fibroblasts developed to blastocysts. Results of the present study clearly demonstrated that gene transfected buffalo EG‐like cells have the ability to form chimeric embryos after injecting into buffalo early embryos and reprogramming ability after NT, which can be employed to produce transgenic buffalos through either embryo chimera or NT.     

Production of transgenic and non-transgenic clones in miniature pigs by somatic cell nuclear transfer

Miniature pigs have been recognized as valuable experimental animals in various fields such as medical and pharmaceutical research. However, the amount of information on somatic cell cloning in miniature pigs, as well as genetically modified miniature pigs, is much less than that available for common domestic pigs. The objective of the present study was to establish an efficient technique of cloning miniature pigs by somatic cell nuclear transfer. A high pregnancy rate was achieved following transfer of parthenogenetic (3/3) and cloned (5/6) embryos using female miniature pigs in the early pregnancy period as recipients after estrus synchronization with prostaglandin F2 alpha analog and gonadotrophins. The production efficiency of the cloned miniature pigs using male and female fetal fibroblasts as nucleus donors was 0.9% (2/215 and 3/331, respectively). Cloned miniature pigs were also produced efficiently (7.8%, 5/64) by transferring reconstructed embryos into the uteri of common domestic pigs. When donor cells transfected with the green fluorescent protein (GFP) gene were used in nuclear transfer, the production efficiency of the reconstructed embryos and rate of blastocyst development were comparable to those obtained by non-transfected cells. When transfected cell-derived reconstructed embryos were transferred to three common domestic pig recipients, all became pregnant, and a total of ten transgenic cloned miniature pigs were obtained (piglet production efficiency: 2.7%, 10/365). Hence, we were able to establish a practical system for producing cloned and transgenic-cloned miniature pigs with a syngeneic background.     

Migration of primordial germ cells isolated from embryonic blood into the gonads after transfer to stage X blastoderms and detection of germline chimaerism by PCR

1. The present study was carried out to determine whether primordial germ cells isolated from embryonic blood can enter the bloodstream and successfully migrate to the germinal ridges of recipient embryos after transfer to stage X blastoderms, and also whether they can differentiate into blood cells, as is suggested in mice. 2. Primordial germ cells were transfected in vitro by lipofection and then transferred to stage X blastoderms. The introduced GFP gene was efficiently expressed in the gonads of 6-d incubated embryos. 3. Freshly collected primordial germ cells were transferred to stage X blastoderms. The fate of the transferred primordial germ cells was traced by detecting the single nucleotide polymorphism in the D-loop region of the mitochondrial DNA in White Leghorn and Barred Plymouth Rock chickens used in this study. The transferred donor primordial germ cell-derived cells were detected in the gonads, but not in the blood cells, of 17-d incubated embryos by PCR. 4. This procedure for primordial germ cell manipulation could provide a novel method of producing germline chimaeric chickens. 5. In conclusion, our findings indicate that primordial germ cells isolated from embryonic blood can migrate to the germinal ridges of recipient embryos after being transferred to stage X blastoderms. Although these transferred primordial germ cells differentiated into germ cells, no differentiation into blood cells was observed.     

利用脂质体法建立转Toll样受体4基因大尾寒羊胎儿成纤维细胞株的研究

利用脂质体转染法获得转Toll样受体4(Toll-like receptors 4,TLR4)基因的成纤维细胞,将其作为供体细胞,再通过体细胞核移植技术构建重构胚,最终生产出转TLR4基因且性别可控的大尾寒羊。本研究通过原代培养大尾寒羊胎儿皮肤成纤维细胞,并进行SRY基因性别鉴定,利用脂质体转染法转入TLR4基因,然后分别从形态学与分子水平检测TLR4基因的表达,将稳定表达转TLR4的成纤维细胞核移植入绵羊去核卵母细胞中构建重构胚。最终获得5个稳定表达TLR4的阳性细胞克隆,经SRY基因性别鉴定为雌性细胞株,通过实时荧光定量PCR分析,在第4代转染的细胞中TLR4表达量最高,比未转染细胞高出7.4816倍(P<0.01),卵裂的重构胚中有EGFP的表达。试验成功构建出含TLR4基因的重构胚,为今后生产出性别可控的抗病转基因绵羊地方新品种奠定基础。     

Establishment of Fetal Large-tailed Han Sheep Fibroblasts Cell Line Transfected with Lipofectamine 2000 Vector Containing TLR4 Gene

Exploiting the method of liposome transfection to obtain modified Toll-like receptors 4(TLR4) gene fibroblast cells as competent donor, build reconstructed embryos, which finally produced transfected TLR4 gene and gender controllable Large-tailed Han sheep by somatic cell nuclear transfer technology.In this study, through primary culturing the fetus dermal fibroblasts from Large-tailed Han sheep, to identify the SRY gene gender.Using the method of liposome transfection transferred TLR4 gene into fibroblast cells, then detected whether TLR4 gene expression stably or not in morphology level and molecular level respectively, transplanting fibroblast cells which stably expressed TLR4 gene into oocytes without nucleus from Large-tailed Han sheep for building reconstructed embryos.To harvest 5 positive clones by fibroblast cells with stable expression level of TLR4.According to the identification of the SRY gene gender, the cell lines were female.The analysis of Real-time fluorescent quantitative PCR, the fourth generation of transfected cells had the highest expression level of TLR4, which were higher than control group in 7.4816 times (P<0.01).The cleavage reconstructed embryos had stable expression level of EGFP.We succeeded in building reconstructed embryos with TLR4 gene and lay the foundation for producing the disease-resistant and gender controllable transgenic sheep in the future.     

Transgenic mouse offspring generated by ROSI

The production of transgenic animals is an important tool for experimental and applied biology. Over the years, many approaches for the production of transgenic animals have been tried, including pronuclear microinjection, sperm-mediated gene transfer, transfection of male germ cells, somatic cell nuclear transfer and the use of lentiviral vectors. In the present study, we developed a new transgene delivery approach, and we report for the first time the production of transgenic animals by co-injection of DNA and round spermatid nuclei into non-fertilized mouse oocytes (ROSI). The transgene used was a construct containing the human CMV immediate early promoter and the enhanced GFP gene. With this procedure, 12% of the live offspring we obtained carried the transgene. This efficiency of transgenic production by ROSI was similar to the efficiency by pronuclear injection or intracytoplasmic injection of male gamete nuclei (ICSI). However, ICSI required fewer embryos to produce the same number of transgenic animals. The expression of Egfp mRNA and fluorescence of EGFP were found in the majority of the organs examined in 4 transgenic lines generated by ROSI. Tissue morphology and transgene expression were not distinguishable between transgenic animals produced by ROSI or pronuclear injection. Furthermore, our results are of particular interest because they indicate that the transgene incorporation mediated by intracytoplasmic injection of male gamete nuclei is not an exclusive property of mature sperm cell nuclei with compact chromatin but it can be accomplished with immature sperm cell nuclei with decondensed chromatin as well. The present study also provides alternative procedures for transgene delivery into embryos or reconstituted oocytes.     

Production of blastocysts after intergeneric nuclear transfer of goral (Naemorhedus goral) somatic cells into bovine oocytes

Interspecies cloning may be a useful method to help conserve endangered species and to study nuclear-cytoplasm interaction. The present study investigated in vitro development of goral (Naemorhedus goral) intergeneric nuclear transfer embryos produced by fusing goral fibroblasts with enucleated metaphase II (MII) bovine oocytes. After two to five passages, serum-starved or non-starved goral skin fibroblast cells were transferred into enucleated MII bovine oocytes. Couplets were electrically fused and chemically activated, and then cultured in either modified synthetic oviduct fluid (mSOF) or tissue culture medium-199 (TCM-199) supplemented with 10% FBS. Serum starvation of donor cells did not affect the fusion rate and or development to of cells to the two-cell stage, to more than 9-cells, or to morulae, regardless of culture medium. Three blastocysts from 202 fused embryos were obtained when embryos reconstructed with non- serum- starved donor cells were cultured in mSOF. However, no blastocysts were obtained when the embryos reconstructed with serum-starved donor cells were cultured in mSOF. The total cell number of goral intergeneric embryos averaged 130.3 (range 105-180). In conclusion, this study demonstrated that bovine oocytes can support blastocyst development after intergeneric SCNT with goral fibroblasts.     

转肌细胞特异表达MSTN基因RNA干涉序列的小鼠成纤维细胞株的筛选

为了筛选肌细胞特异表达MSTN基因RNA干涉序列的小鼠成纤维细胞株,研究利用人工合成的小鼠肌肉启动子SP,连接前期工作中获得带有GFP基因的小鼠MSTN基因RNA干涉载体pR-NAT-M1,构建真核表达载体pRNAT-SP-M1,将pRNAT-SP-M1线性化后转染小鼠成纤维细胞并通过300μg/mL G418筛选获得转基因阳性细胞。结果表明:获得的转基因阳性细胞呈现正常的小鼠成纤维细胞的梭形,且在荧光显微镜下呈现出表达绿色荧光蛋白的绿色;转基因阳性细胞的生长曲线呈"S"形;转基因阳性细胞经冷冻复苏后,仍具有正常的细胞形态和增殖特性;PCR鉴定结果显示转基因阳性细胞基因组DNA中整合有pRNAT-SP-M1序列。说明成功获得了转肌细胞特异表达的MSTN基因RNA干涉序列小鼠成纤维细胞株。     

Efficiency of Two Enucleation Methods Connected to Handmade Cloning to Produce Transgenic Porcine Embryos

The purpose of our work was to establish an efficient-oriented enucleation method to produce transgenic embryos with handmade cloning (HMC). After 41–42 h oocytes maturation, the oocytes were further cultured with or without 0.4 μg/ml demecolcine for 45 min [chemically assisted handmade enucleation (CAHE) group vs polar body (PB) oriented handmade enucleation (OHE) group respectively]. After removal of the cumulus cells and partial digestion of the zona pellucida, oocytes with visible extrusion cones and/or polar bodies attached to the surface were subjected to oriented bisection. Putative cytoplasts without extrusion cones or PB were selected as recipients. Two cytoplasts were electrofused with one transgenic fibroblasts expressing green fluorescent protein (GFP), while non-transgenic fibroblasts were used as controls. Reconstructed embryos were cultured in Well of Wells (WOWs) with porcine zygote medium 3 (PZM-3) after activation. Cleavage and blastocyst rates were registered on day 2 and day 7 of in vitro culture respectively. Meanwhile, the total blastocyst cell number was counted on day 7. We found that the difference was only observed between blastocyst rates (38.6 ± 2% vs 48.1 ± 3%) of cloned embryos with GFP transgenic fibroblast cells after CAHE vs OHE. With adjusted time-lapse for zonae-free cloned embryos cultured in WOWs with PZM-3, it was obvious that in vitro developmental competence after CAHE was compromised when compared with the OHE method. OHE enucleation method seems to be a potential superior alternative method used for somatic cell nuclear transfer (SCNT) with transgenic fibroblast cells.     

脂质体介导抗猪瘟病毒基因转染小鼠胚胎成纤维细胞的研究

本研究旨在探索脂质体介导抗猪瘟病毒基因重组质粒PGPUG/GFP/Neo转染小鼠胚胎成纤维细胞的条件,为构建疾病模型动物及抗猪瘟病毒转基因猪提供技术平台。本研究比较了不同的小鼠胚胎成纤维细胞分离培养方法,将培养至3~5代的胚胎儿成纤维细胞,通过脂质体(LiPofectamine^TM 2000)介导转染抗猪瘟病毒基因重组质粒PGPUG/GFP/Neo。结果显示,在所选用的不同浓度脂质体和重组质粒,以及不同转染时间的组合中,2 μL脂质体介导1.5 μg重组质粒,转染6 h时可获得19%的转染效率,极显著高于其他剂量和时间组合(P＜0.01)。这些结果表明,脂质体、重组质粒及转染时间的优化组合,能有效介导抗猪瘟病毒基因重组质粒PGPUG/GFP/Neo转染小鼠胚胎成纤维细胞。     

Transgenic chimera quail production by microinjecting lentiviral vector into the blood vessel of the early embryo

In the past, several strategies have been used to generate transgenic birds. The most successful method has proven to be injection of lentiviral vector into the subgerminal cavity of the newly laid egg. In this study, we directly injected lentiviral vector into the blood vessel of HH13–15 quail embryos to produce transgenic chimeras. In the manipulated, hatched birds, the green fluorescent protein (GFP) gene driven by a cytomegalovirus (CMV) promoter was extensively expressed. All tissues analyzed were GFP‐positive, and gonad cells from some of the manipulated embryos expressed GFP. The semen genome of 21.4% of mature male birds was determined to be GFP‐positive by PCR, indicating these male birds were transgenic chimeras.     

ZB transposon and chicken vasa homologue (Cvh) promoter interact to increase transfection efficiency of primordial germ cells in vivo

ABSTRACT

1. In order to increase the efficiency of generating transgenic chicken, this trial focused on two points: primordial germ cells (PGCs）transfection in vivo and a germline-specific promoter.

2. In order to transfect PGCs in vivo, two plasmids (pZB-CAG-GFP, pCMV-ZB）were co-injected into chicken embryos via the subgerminal cavity at Hamburger and Hamilton (HH) stage 2–3 or via blood vessel at HH stage 13–14. Results showed that the percentage of GFP+ embryos, viability and hatching rate of embryos injected at HH stage 13–14 were significantly higher than that at HH stage 2–3.

3. Two plasmid transposon systems were used for chicken embryo micro-injections. The donor plasmid, with a green fluorescent protein (GFP) reporter gene, was mediated by the ZB transposon. The helper plasmid was a transposase expression vector driven by the promoter of the chicken vasa homologue (Cvh) gene or Human cytomegalovirus (CMV) promoter. Results showed that 60.98% of gonads in Cvh group expressed GFP, which was 52.50% higher than seen in the CMV group. Only gonad tissue from the Cvh group showed any GFP signal, whereas both gonads and other tissues in the CMV group showed green fluorescence.

4. The data suggested that ZB transposon-mediated gene transfer was efficient for transfecting PGCs in vivo; the Cvh promoter drove the transposase gene specifically in the germline and increased the efficiency of germline transmission. Blood vessels injection at HH stage 13–14 may be a more efficient route for PGCs transfection in vivo.     

Controversial aspect of using GFP as a marker for the production of transgenic cattle

The objective of this study was to examine the feasibility of identification and selection of cattle embryos based on green fluorescence (GFP-positive) in order to obtain calves carrying an integrated transgene. The construct used (pbLGTNF-EGFP) contained the human tumor necrosis factor alpha (hTNFalpha) gene fused to the bovine beta-lactoglobulin promoter (bLG) in plasmid vector pCX-EGFP. In four experiments, 76 zygotes were injected; eight of them developed to the morulae/blastocysts stage of which only five were GFP positive (one of them 100%, one-50%, three- 25%). All of the GFP positive embryos were transferred to recipients. Two calves were born: one after transfer of the 100% GFP positive embryo and the other after transfer of one of the 25% GFP positive embryos. Both animals were healthy with normal weight when compared to two control calves. The integration of pbLGTNF-EGFP in the host genome could not be detected in either of the calves, suggesting that GFP is an unreliable marker for preimplantation screening of embryos.     

Timing and uniformity of embryonic gene activation affect subsequent pre-implantation development of cloned bovine embryos

In the present study, we examined the timing of onset, intensity, and mosaicism of embryonic gene expression in bovine nuclear transfer (NT) embryos. The relationship between gene expression and early embryonic development was also examined. To monitor the gene expression of NT embryos, we produced NT embryos with bovine transfected fibroblasts carrying a firefly luciferase gene under the control of a chicken beta-actin promoter, an expression system that has previously been shown to be representative of embryonic gene expression in mice. Photon count imaging showed that luciferase luminescence began in NT embryos with fibroblasts 48 hours post fusion (hpf) and reached a plateau at the 4- to 8-cell stage at 60 hpf. Only 4- to 8-cell NT embryos luminescent by 60 hpf developed to the blastocyst stage. At 60 hpf, strongly luminescent embryos developed to the blastocyst stage at a higher rate (P<0.05) than embryos with weak or absent luminescence. However, embryos with mosaic luminescence developed at a much lower rate (P<0.05) than those with whole-embryo luminescence, even if the embryos exhibited strong luminescence. Our results indicate that precise and uniform embryonic gene expression at the 4- to 8-cell stage at 60 hpf may be closely related to development of bovine NT embryos to the blastocyst stage.     

Effect of soft X-ray irradiation on the migratory ability of primordial germ cells in chickens

1. The present study was conducted to elucidate the effect of soft X-ray irradiation on the migratory ability of primordial germ cells (PGCs) to the germinal ridges of chicken embryos. 2. PGCs (Barred Plymouth Rock, BPR) were isolated from embryonic blood and irradiated with soft X-rays for 1-10 min. Then, the PGCs were transfected in vitro with GFP gene by lipofection. The manipulated PGCs were transferred to recipient embryos (White Leghorn, WL) and migration to the germinal ridges was analysed by examining GFP gene expression in the gonads of recipient embryos under UV light at x40 magnifications. The expression of GFP gene was detected in all the gonads of recipient embryos examined up to 10.5 d of culture. 3. Migration of PGCs irradiated with soft X-rays to the germinal ridges was also confirmed by detecting a single nucleotide polymorphism in the D-loop region of the mitochondrial DNA of BPR and WL chickens. Freshly collected PGCs (BPR) were transferred to the bloodstream of recipient embryos (WL). The fate of the transferred donor PGCs was traced by detecting the single nucleotide polymorphism in the D-loop region of the mitochondrial DNA in BPR and WL used in this study. Transferred donor PGC-derived cells were detected in all the gonads of 17-d cultured embryos by PCR. 4. The results suggest that PGCs irradiated with soft X-rays still retain the ability to migrate to the germinal ridges of recipient embryos.