CRISPR/Cas9-induced knock-out/-in can be occurred at specific locus in the genome by non-homologous end joining (NHEJ) or homology directed repair (HDR). Here, we demonstrate the targeted insertion into the specific loci of embryo fertilized by semen from transgenic cattle via CRISPR/Cas9 system. Recently, we published on the efficient generation of transgenic cattle using the DNA transposon system (Yum et al. Sci Rep. 2016 Jun 21;6:27185). In the study, eight transgenic cattle were born following transposon-mediated gene delivery system (Sleeping Beauty and Piggybac transposon system) via microinjection. In the analysis of their genome stability using next-generation sequencing, there was no significant difference in the number of genetic variants between transgenic and non-transgenic cattle. All the transgenic cattle have grown up to date (the oldest age: 33 months old, the youngest age: 15 months old) without any health issue. One of transgenic male cattle expressing GFP reached puberty and semen was collected. Over 200 frozen semen straws were produced and some were used for in vitro fertilization (IVF). On seven days after IVF, expression of GFP was observed at blastocyst stage and was seen in 80% of the embryos. Another application is to edit the GFP locus of the transgenic cattle because long-term and ubiquitous expression of transgene didn’t affect their health. In one cell stage embryos produced using GFP frozen-thawed semen, microinjection of sgRNA for GFP, Cas9, together with donor DNA that included RFP and homology arms to link the double-strand break of sgRNA target site into fertilized eggs resulted in expression of RFP. This indicated that the GFP locus of transgenic cattle shows potential candidates for stable insertion of the functional transgene. Knock-out/-in for editing GFP locus using CRISPR-Cas9 might be a valuable approach for the next generation of transgenic models by microinjection. In conclusion, we demonstrated P-112 that transgenic cattle via transposon system are healthy to date and germ-line competence was confirmed. The GFP locus will be used as the potential target site for future gene engineering via genome-editing technology. Finally, all those animals could be a valuable agricultural and veterinary science resource for studying the effects of gene manipulation on biomedical research and medicine. This work was supported by BK21 PLUS Program for Creative Veterinary Science and Seoul Milk Coop (SNU 550-20160004).

Understanding the behavior of transgenes introduced into oocyte or embryos is essential for evaluating the methodologies for transgenic animal production. To date, many studies have reported the production of transgenic pig embryos with, however, low efficiency in environment of blastocyst production. The aim of present study was to determine the expression and duration of transgene transferred by intracytoplasmic sperm injection-mediated gene transfer (ICSI-MGT). Embryos obtained from the ICSI-MGT procedure were analysed for the expression of GFP and then for the transmission of the transgene. Briefly, fresh spermatozoa were bound to exogenous DNA after treatment by Triton X-100 and Lipofectin. When ICSI-MGT was performed using sperm heads with tails removed, the yield of blastocyst (25.3%), treated with Lipofectin (18.8%) and Triton X-100 (19.2%) were observed. Treatments of Lipofectin or Triton X-100 did not further improve the rates of blastocysts. Moreover, the apoptosis rates of embryos were obtained from the control and LIpofectin groups (8.7%, 9.7%, respectively), but were significantly higher in the Triton X-100 group (13.0%). Our results demonstrated that ICSI-MGT caused minimal damage to oocytes that could develop to full term. Moreover, the embryos derived by ICSI-MGT have shown prolonged exogenous DNA expression during preimplantation stage in vivo. However, more efforts will be required to improve the procedures of both sperm treatments cause of high frequency of mosaicisms.

The purpose of this study is to develop transgenic cell line expressing targeted human granulocyte colony stimulating factor (hGCSF) and green fluorescence protein (GFP) genes as well as production of Somatic Cell Nuclear Transfer (SCNT) embryos derived from co-expressed transgenic donor cells. Constructed pPiggy-mWAP-hGCSF-EF1-GFP vector was chemically transfected into bovine fetus cells and then, only GFP expressed cells were selected as donor cells for SCNT. Cleavage and blastocyst rates of parthenogenetic, SCNT embryos using non-TG cell and hGCSF-GFP dual expressed SCNT embryos were examined (cleavage rate: 78.0±2.8 vs. 73.1±3.2 vs. 70.4±4.3%, developmental rate: 27.2 ±3.2 vs. 21.9±3.1 vs. 17.0±2.9%). Result indicated that cleavage and blastocyst rates of TG embryos were significantly lower (P<0.05) than those of parthenogenetic and non-TG embryos, respectively. In this study, we successfully produced hGCSF-GFP dual expressed SCNT embryos and cryopreserved to produce transgenic cattle for bioreactor system purpose. Further process of our research will transfer of transgenic embryos to recipients and production of hGCSF secreting cattle.

Two piglets and one juvenile pig were used to investigate closely what types of cells express green fluorescent protein (GFP) and if any, whether the GFP-tagged cells could be used for stem cell transplantation research as a middle-sized animal model in bone marrow cells of recloned GFP pigs. Bone marrow cells were recovered from the tibia, and further analyzed with various cell lineage markers to determine which cell lineage is concurrently expressing visible GFP in each individual animal. In the three animals, visible GFP were observed only in proportions of the plated cells immediately after collection, showing 41, 2 and 91% of bone marrow cells in clones #1, 2 and 3, respectively. The intensity of the visible GFP expression was variable even in an individual clone depending on cell sizes and types. The overall intensities of GFP expression were also different among the individual clones from very weak, weak to strong. Upon culture for 14 days in vitro (14DIV), some cell types showed intensive GFP expression throughout the cells; in particular, in cytoskeletons and the nucleus, on the other hand. Others are shown to be diffused GFP expression patterns only in the cytoplasm. Finally, characterization of stem cell lineage markers was carried out only in the clone #3 who showed intensive GFP expression. SSEA-1, SSEA-3, CD34, nestin and GFAP were expressed in proportions of the GFP expressing cells, but not all of them, suggesting that GFP expression occur in various cell lineages. These results indicate that targeted insertion of GFP gene should be pursued as in mouse approach to be useful for stem cell research. Furthermore, cell- or tissue-specific promoter should also be used if GFP pig is going to be meaningful for a model for stem cell transplantation.

The possibility of producing transgenic embryos expressing the green fluorescence protein (GFP) gene have been evaluated after transfer of exogenous gene into the porcine zygote cytoplasm using the intracytoplasm sperm injection (ICSI) as gene delivery method. For DNA binding to sperm heads, 0.05% Triton X-100 or Lipofectin was used. After injection of the sperm bound to DNA by means of Lipofectin or Triton X-100 triturate, the blastocyst formation rates on day 6 were not significantly different from that of ICSI only group (18.8, 19.2 and 25.3%). In terms of GFP expression, more embryos were in GFP form in Triton X-100 group than in Lipofectin group (40.6 vs 36.4%), while percentage of non-mosaic embryos expressing the GFP gene in all blastomere was higher (P<0.05) in Lipofectin group than in Triton X-100 group (4.2 vs 0.9%). ICSI embryos derived from sperm treated with Lipofectin/DNA complex was transferred into 3 recipients and were collected by uterine flushing on days 5, 7 and 15 after embryo transfer, and then GFP expression was observed by a fluorescence microscopy. Over 26% of the collected embryos were normally expressed GFP gene. These results suggest that foreign gene transfer method with DNA bound sperm caused minimal damage to structure of oocytes that can result to full development of porcine embryos. This was confirmed in this study when the embryos that were transferred after ISCI of DNA bound sperm had a normal development and gene expression until preimplantation.

본 연구에서는 retrovirus를 이용한 유전자 전이에 있어서 대두되는 큰 문제점의 하나인 외래 유전자의 지속적인 발현으로 인한 개체의 생리적인 손상을 최소화하기 위하여 tetracycline계 물질의 공급 여부에 따라서 발현을 유도적으로 조절할 수 있는 one vector 형태의 Tet-On system을 구축하고자 하였다. 또한 WPRE 서열을 이 vector 상에 도입하여 유도적 조건에서 외래 유전자의 발현이 보다 강하게 일어날 수 있는 효율적인 retrovirus vector system을 확립하고자 하였다. 구축한 각각의 vector system에서 fluorometry와 western blotting을 이용하여 GFP 유전자의 발현 정도를 비교 측정한 결과, RevTRE-EGFP-WPRE-RSVp-rtTA2SM2 virus를 이용하여 유전자를 전이시킨 표적세포에서 GFP의 절대적인 발현량이 가장 큰 것으로 나타났고, 유전자 발현의 turn on/off에 의한 유도율은 RevTRE-EGFP-RSVp-rtTA2SM2-WPRE virus의 경우에서 8∼21배로 가장 높은 것으로 나타났다. 이상의 결과에서 외래 유전자의 발현을 효율적으로 조절할 수 있는 vector system은 WPRE가 rtTA2SM2 서열의 3에 위치한 형태로, 이 system을 이용하여 생산한 고감염가의 virus는 유전자 치료나 형질전환 동물의 생산에 있어서 요구되는 외래 유전자의 발현을 효율적으로 조절할 수 있는 수단이 될 것이다.

본 실험에서는 외래 유전자의 효율적인 발현을 위하여 GFP 표지유전자를 이용하여 여러 종류의 promoter를 검정하였다. 또한, retrovirus vector에 WPRE 서열을 도입함으로써 GFP 유전자의 발현 증가 여부를 확인하였다. 모든 표적 세포에 있어서 UbC와 β-actin promoter에 비해 RSV와 CMV promoter 통제하의 GFP의 발현이 더 강하게 나타났으며, 특히 CEF 세포에서는 RSV promoter가 가장 우수한 것으로 확인되었다. WPRE의 도입으로 인한 발현율의 증가는 CEF를 제외한 세포주에서 promoter의 종류에 관계없이 확인되었다. 이상의 결과로 각 세포주는 promoter에 따라 발현 양상이 약간의 차이를 보이고 있으나 RSV와 CMV promoter에서 유전자의 발현이 보다 효율적이며, WPRE 서열이 도입된 경우에 HeLa와 PFF 세포에서 발현이 현저히 증가하는 것을 확인할 수 있었다. 이러한 연구 결과는 효율적인 유전자의 발현 체계를 확립하는데 기여함으로써 더 나아가 유전자 치료나 형질전환 동물생산에 적극적으로 활용되어질 수 있을 것이다.

형질전환 가축을 생산하기 위하여 최근 체세포 복제 기법을 이용하고 있다. 이러한 체세포를 이용한 형질전환 동물의 생산에는 체세포내에 유전자의 도입 효율이 직접적인 영향을 주게 된다. 따라서 본 연구는 세포내 유전자의 transfection 효율을 높이고자 한우의 체세포를 이용하여 여러 가지 조건에서 유전자 도입을 실시하였다. 세포내 유전자 도입 방법은 electroporation (EP) 방법을 이용하였다. 사용한 세포는 소의 귀세포(KbESF), 태아섬유아세포 (KbFF), 그리고 대조구로서 CHO cell을 이용하여 GFP 유전자를 도입하였다. EP는 0.4 cm cuvette을 사용하였고, voltage는 0.25 kV, 그리고 field strength 는 0.625 kV/cm 조건으로 실시하였으며, pulse times은 각각 1, 2, 또는 3회를 사용하였다. KbFF와 KbESF에서는 각각 pulse times을 증가시킬수록 유전자도입 세포수가 증가하였으나 (KbFF: 81, 634, 1,065 cells/ cells, KbESF: 1,011, 5,567, 15,408 cells/ cells), CHO cell에서는 pulse times을 증가시킬 수록 오히려 유전자도입 세포수가 감소하였다 (CHO: 1,591, 687, 297 cells/ cells). 그리고 2주 동안 neo selection을 실시 한 결과 KbFF, KbESF, CHO에서 각각 93, 35, 184 colony가 선발되었으며, 이 중 65.6%, 8.6%, 4.3% 가 GFP 형광 발현 colony로 나타났다. 한편 CHO cell에서 transfection cell수가 감소된 것은 EP의 자극으로 인해 손상된 세포가 많이 발생한 것으로 나타났다. 또한 neo selection에서 선발된 colony중 GFP가 발현되지 않거나 일부만 발현되는 colony들이 많이 발생하였는데, 이것은 세포내 유전자가 transfection되지 않은 세포도 neo selection에서 선발된다는 것을 제시하고 있다. 따라서 체세포를 이용한 형질전환동물 생산을 위해서는 세포내 유전자 도입과 선발 과정에서 나타난 colony에 대하여 보다 엄격한 screen을 하는 것이 필요한 것으로 생각된다.

Transgenic animals production tools have been valuable for research and purpose. The current methods of gene transfer, microinjection and nuclear transfer, which are widely used in transgenic animal production, but all most methods has only had limited success in production of larger species. Here, we report the possibility of a sperm-mediated gene transfer method in porcine embryos. Oocytes were collected from ovaries harvested at a local slaughterhouse were matured in 500 drops of TCM-199 under mineral oil at 38.5 in a humidified atmosphere of 5%CO2 in air. After 42-43h of in vitro maturation oocytes were denuded. for sperm injection into the cytoplasm of the porcine oocytes, sperm suspension in NIM medium are subjected extraction with TritonX-100 before mixing with a green fluorescent gene (GFP). Sperm with Tritonx-100 were prepared by adding TritonX-100 to a final volume of 0.05% in the sperm suspension and mixing by trituration for 60s before two wishes in NIM medium at 2. A(ter wishing, sperm were mixed with TritonX-100 at followed by washes at 2. Sperm were resuspended in ice cold NIM to a final volume of 400 and 2-20ng/ DNA were triturated on ice for 60s. All microinjection was performed in HEPES-buffered CZB medium at room temperature within 2h. After culture in NCSU-23 for 72h, percent of porcine embryos transfected GFP gene are 20.7%(6/29) in 20ng/ sperm-DNA mixed group and other groups were 3.7 %(2/54)and 4.7%(3/67). These data suggests that sperm-mediated gene transfer method should be used to the production tool of transgenic pig efficiently.

The efficiency of transgenic livestock animal production may be improved by early selection of transgenci preimplantation embryos. To examine the possibility of GFP gene as a non-invasive marker for the early screening of transgenic embryo, the GFP gene was microinjected into rabbit zygotes and the later stages of preimplantation embryos were examined for the expression of GFP. The presence of injected DNA was detected by PCR analysis and the expression of GFP was detected by observing green fluorescence in embryos under a fluorescent microscope. Out of 108 GFP gene-injected rabbit zygotes, seventy three(67.6%) were fluorescence-positive. When 11 fluroresecence-positive blastocysts were analyzed for the presence of GFP gene by PCR, 6(54.5%) were positive, and all of the 8 flrouescence-negative blastocysts were also negative by PCR. The results indicate that the screening of transgene in rabbit embryos by PCR analysis and GFP detection could be a promising method for the preselection of transgenic embryos.