Background: Efficient gene editing technology is needed for successful knock-in. Homologous recombination (HR) is a major double-strand break repair pathway that can be utilized for accurately inserting foreign genes into the genome. HR occurs during the S/G2 phase, and the DNA mismatch repair (MMR) pathway is inextricably linked to HR to maintain HR fidelity. This study was conducted to investigate the effect of inhibiting MMR-related genes using CdCl2, an MMR-related gene inhibitor, on HR efficiency in HC11 cells. Methods: The mRNA and protein expression levels of MMR-related genes (Msh2, Msh3, Msh6, Mlh1, Pms2), the HR-related gene Rad51, and the NHEJ-related gene DNA Ligase IV were assessed in HC11 cells treated with 10 μM of CdCl2 for 48 hours. In addition, HC11 cells were transfected with a CRISPR/sgRNA expression vector and a knock-in vector targeting Exon3 of the mouse-beta casein locus, and treated with 10 μM cadmium for 48 hours. The knock-in efficiency was monitored through PCR. Results: The treatment of HC11 cells with a high-dose of CdCl2 decreased the mRNA expression of the HR-related gene Rad51 in HC11 cells. In addition, the inhibition of MMR-related genes through CdCl2 treatment did not lead to an increase in knock-in efficiency. Conclusions: The inhibition of MMR-related gene expression through high-dose CdCl2 treatment reduces the expression of the HR-related gene Rad51, which is active during recombination. Therefore, it was determined that CdCl2 is an inappropriate compound for improving HR efficiency.
Increasing the efficiency of HR (homologous recombination) is important for a successful knock-in. Rad51 is mainly involved in homologous recombination and is associated with strand invasion. The HR-related mismatch repair system maintains HR fidelity by heteroduplex rejection and repair. Therefore, the purpose of this study is to control Rad51, which plays a critical role in HR, through UV-induced DNA damage. It is also to confirm the effect on the expression of MMR related genes (Msh2, Msh3, Msh6, Mlh1, Pms2) and HR-related genes closely related to HR through treatment with the MMR inhibitor CdCl2. The mRNA expression of Rad51 gene was confirmed in both HC11 cells and mouse testes, but the mRNA expression of Dmc1 gene was confirmed only in mouse testes. The protein expression of Rad51 and Dmc1 gene increased in UV-irradiated HC11 cells. After 72 hours of treatment with 1 μm of CdCl2, the mRNA expression level of Msh3, Pms2, and Rad51 decreased, but the mRNA expression level of Msh6 and Mlh1 increased in HC11 cells. There was no significant difference in Msh2 mRNA expression between CdCl2 untreated-group and the 72 hours treated group. In conclusion, HR-related gene (Rad51) was increased by UV-induced DNA damage. Treatment of the MMR inhibitor CdCl2 in HC11 cells decreased the mRNA expression of Rad51.
The Transgenic livestock can be useful for the production of disease-resistant animals, pigs for xenotranplantation, animal bioreactor for therapeutic recombinant proteins and disease model animals. Previously, conventional methods without using artificial nuclease-dependent DNA cleavage system were used to produce such transgenic livestock, but their efficiency is known to be low. In the last decade, the development of artificial nucleases such as zinc-finger necleases (ZFNs), transcription activator-like effector nucleases (TALENs) and clustered regulatory interspaced short palindromic repeat (CRISPR)/Cas has led to more efficient production of knock-out and knock-in transgenic livestock. However, production of knock-in livestock is poor. In mouse, genetically modified mice are produced by co-injecting a pair of knock-in vector, which is a donor DNA, with a artificial nuclease in a pronuclear fertilized egg, but not in livestock. Gene targeting efficiency has been increased with the use of artificial nucleases, but the knock-in efficiency is still low in livestock. In many research now, somatic cell nuclear transfer (SCNT) methods used after selection of cell transfected with artificial nuclease for production of transgenic livestock. In particular, it is necessary to develop a system capable of producing transgenic livestock more efficiently by co-injection of artificial nuclease and knock-in vectors into fertilized eggs.
The knock-in efficiency is very important to manipulate gene editing in the transgenic domestic animal. Recently, it is reported that transiently loosen nucleosome folding of transcriptionally inactive chromatin might have potential tp enhance the homologouse recombination efficiency. Histone deacetylases (HDAC) are a class of enzymes that remove acetyl groups from an amino acid on a histone. This is important because DNA is wrapped around histones, and DNA expression is regulated by acetylation and de-acetylation. In this study, Mac-T cell were treated with 10uM VPA (valproic acid, HDAC inhibitor) for 24 h and transfected with Knock-in vector and TALEN at targeting of β-casein gene. After 3 day of transfection, knock-in efficiency was confirmed by PCR. The level of HDAC2 protein in Mac-T cells was decreased by VPA treatment. The knock-in efficiency in the Mac-T cell with treated HDAC inhibitor was higher than cell not treated HDAC inhibitor. These results indicated that chromatin modification by HDAC inhibitor enhances homologous recombination efficiency in the Mac-T cell.
This study aimed to produce high-quality blastocysts and establish appropriate microinjection conditions for the introduction of target gene. First, we identified embryo development to the blastocyst stage after microinjection using the CRISPR/Cas9 system on the Cas9 protein or mRNA. As a result, we confirmed that blastocyst development in the Cas9 mRNA injected group significantly increased when compared to the Cas9 protein injected group (p<0.05). However, the blastocyst gene targeting rate increased in the Cas9 protein injected group when compared to the Cas9 mRNA injected group (p<0.05). Next, we treated the injection medium with 10 μg/ml of cytochalasin B (CB), and the microinjected embryos were cultured in CR1-aa medium supplemented with 0.1 μM of melatonin (Mela). Consequently, the blastocyst formation rate significantly increased in the CB treated group (p<0.05). After microinjecting embryos with the CB treated injection medium, we investigated blastocyst formation and quality via Mela treatment. Consequently, the Mela treated group demonstrated significantly increased blastocyst formation rates when compared to the non-treated group (p<0.05). Furthermore, immunofluorescence assay using RAD51 (DNA repair detection protein) and H2AX139ph (DNA damage detection protein) showed an increase in RAD51 positive cells in Mela treated embryos. Therefore, we verified the improvement in knock-in efficiency in microinjected bovine embryos using Cas9 protein. These results also demonstrated that the positive effect of the CB and Mela treatments improved the embryonic developmental competence and blastocyst qualities in genetically-edited bovine embryos.
The knock-in efficiency in the fibroblast is very important to produce transgenic domestic animal using nuclear transfer. In this research, we constructed three kinds of different knock-in vectors to study the efficiency of knock-in depending on structure of knock-in vector with different size of homologous arm on the β-casein gene locus in the somatic cells; DT-A_cEndo Knock-in vector, DT-A_tEndo Knock-in vector I, and DT-A_tEndo Knock-in vector II. The knock-in vector consists of 4.8 kb or 1.06 kb of 5’ arm region and 1.8 kb or 0.64 kb of 3’ arm region, and neomycin resistance gene(neor) as a positive selection marker gene. The cEndo Knock-in vector had 4.8 kb and 1.8 kb homologous arm. The tEndo Knock-in vector I had 1.06 kb and 0.64 kb homologous arm and tEndo Knock-in vector II had 1.06 kb and 1.8 kb homologous arm. To express endostatin gene as transgene, the F2A sequence was fused to the 5’ terminal of endostatin gene and inserted into exon 7 of the β-casein gene. The knock-in vector and TALEN were introduced into the bovine fibroblast by electroporation. The knock-in efficiencies of cEndo, tEndo I, and tEndo II vector were 4.6%, 2.2% and 4.8%, respectively. These results indicated that size of 3’ arm in the knock-in vector is important for TALEN-mediated homologous recombination in the fibroblast. In conclusion, our knock-in system may help to create transgenic dairy cattle expressing human endostatin protein via the endogenous expression system of the bovine β-casein gene in the mammary gland.
Many transgenic domestic animals have been developed to produce therapeutic proteins in the mammary gland. However, purification of therapeutic proteins from transgenic milk are very important for productivity of recombinant protein. Development of a knock-in vector system is needed to improve production of therapeutic proteins. In this study, we are develop Knock-in vector to express human Erythropoietin protein (hEPO) using Gluthathione S-transferase (GST) fusion system on mouse β-casein exon 3 locus. The knock-in vector consisted of the 5 homologous arm (1.02 kb), GST, PreScission protease site, hEPO cDNA, BGH polyA signal, CMV-EGFP, and 3homologous arm(1.81 kb). The analysis of nucleotide and amino acid sequence revealed that GST-hEPO mRNA is probably translated with the mouse β-casein sequence and the β-casein-GST-hEPO fusion protein is probably secreted by ER-Golgi pathway. After that, the hEPO protein can be cleaved to remove the GST from the fusion protein by PreScission protease during purification of recombinant protein. This knock-in vector may help to create transgenic mouse expressing human Erythropoietin protein via the endogenous expression system of the mouse β-casein gene in the mammary gland.
The production of therapeutic proteins from transgenic animals is one of the most important successes of animal biotechnology. Endostatin is 20 KDa C-terminal fragment derived from type XVIII collagen and an endogenous inhibitor of tumor growth by inhibition of angiogenesis. In this study, we are developed knock-in vector consists of 5’ arm region (1.02 kb), human Endostatin cDNA, CMV-EGFP, and 3’ arm region (1.83 kb). To express Endostatin gene as transgene, the F2A sequence was fused to the 5’ terminal of Endostatin gene and inserted into exon 3 of the β -casein gene. If this knock-in vector is inserted into the porcine β-casein gene locus by homologous recombination, human Endostatin mRNA are expressed using the gene regulatory region of the β-casein. Also, the β-casein and Endostatin fusion protein is translated and Endostatin protein is separated by F2A self cleavage during translation. In conclusion, our knock-in vector may help to create transgenic pig expressing human Endostatin protein via the endogenous expression system of the porcine β-casein gene in the mammary gland.
The objective of this study was to investigate the result of in vivo embryo collection and pregnancy rate after embryo transfer using sex-sorted sperm of Korean brindle cattle. Donor Korean brindle cattle superovulation treated by decreasing dose of FSH injection. Embryos were recovered on 7 days after the third artificial insemination. Control group semen straw used artificial insemination contained 20 million sperm. Sex-sorted semen straws contained 4 million sperm or 10 million sperm. As for the result of the recovery of the in vivo embryos derived from sex-sorted sperm, the number of transferable embryos was significantly highly recovered to be 6.20±2.28/donor from the control group and was significantly lowly recovered to be 1.57±1.72/donor from the group treated at a sperm concentration of 10×106 (p<0.05). The number of unfertilized embryo was 0.8±1.30/donor in control group which was significantly lower than the group treated at a sperm concentration of 4×106 (p<0.05). However, there was no significant difference in the number of undeveloped ova between control and treatment groups. Pregnancy rate after embryo transfer was shown to be 35.00% in control group and 12.50% in treatment group. The karyotype analysis of the calf derived from sex-sorted sperm resulted in a similar chromosomal distribution pattern (2n=60, XX) compared to those of common Korean native cattle.
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.
동물의 장기를 인간에게 이식하게 되면 초급성거부반응(Hyperacute rejection, HAR)이 일어난다. 초급성거부반응은 면역계의 구성요소 중 보체(complement)에 의해 일어나는 거부반응으로 돼지의 혈관세포 표면에 있는 Galα(1,3)Gal 당분자에 인간의 항체가 즉각 반응하기 때문에 일어나며, α1,3-galactosyltransferase(α1,3-GT) 유전자는 돼지 혈관세포 표면의 Galα(1,3)Gal 당분자 생성에 관여한다. 따라서 인간에게 돼지의 장기를 이식하기 위해서는 α1,3-galactosyltransferase 유전자를 제거하는 것이 필요한 것으로 알려져 있다. 본 연구실의 이전 연구에서, 시카고 미니돼지 귀체세포에서 상동 재조합(Homologous recombination)을 통해 α1,3-galactosyltransferase 유전자가 제거된 체세포를 개발한 바 있으며, 이 체세포를 통하여 α1,3-GT 유전자가 제거된 돼지도 생산된 바 있다. 본 연구에서는, human serum 처리 시 돼지 세포를 보호해 준다고 보고되고 있는 human complement regulator인 human Decay-accelerating factor(hDAF)와 human α1,2-fucosyltransferase(hHT)유전자를 α1,3-GT 유전자 위치에 gene targeting하여 동시에 hDAF와 hHT가 발현하는 체세포를 개발하였다. Knock-in vector는 hDAF와 hHT 두 유전자가 발현할 수 있도록 IRES로 연결하였으며, α1,3-GT 유전자의 start codon을 이용하여 발현할 수 있도록 구축하였다. 구축한 vector는 electroporation을 통해 미니돼지 체세포에 도입하였으며, PCR 결과, α1,3-GT 유전자 위치에서 상동 재조합이 일어났음을 확인하였다. Positivenegative 선별 방법을 통해 얻은 gene targeting 된 체세포는 RT-PCR에 의해 hDAF와 hHT 유전자의 발현이 확인되었으며, 대조군(NIH minipig)에 비해 α1,3-GT 유전자의 발현이 감소하였다. 또한 이들 세포에 100% human complement serum을 처리하였을 때 knock-in 세포가 대조군에 비해 30% 정도 더 높은 생존율을 보였다. 따라서 개발된 체세포는 이종간 장기이식을 위한 돼지 생산과 함께 이를 이용한 이종간의 장기 이식 시 초급성 거부반응을 억제하는 데 사용될 수 있을 것으로 생각된다.
The specific genetic modification in porcine somatic cells by gene targeting has been very difficult because of low efficiency of homologous recombination. To improve gene targeting, we designed three kinds of knock-out vectors with α1,3-galactosyltransferase gene (α1,3-GT gene), DT-A/pGT5’/neo/pGT3’, DT-A/NLS/pGT5’/neo/pGT3’ and pGT5’/neo/ pGT3’/NLS. The knock-out vectors consisted of a 4.8-kb fragment as the 5’ recombination arm (pGT5’) and a 1.9-kb fragment as the 3’ recombination arm (pGT3’). We used the neomycin resistance gene (neo) as a positive selectable marker and the diphtheria toxin A (DT-A) gene as a negative selectable marker. These vectors have a neo gene insertion in exon 9 for inactivation of α1,3-GT locus. DT-A/pGT5’/neo/pGT3’ vector contain only positive-nega-tive selection marker with conventional targeting vector. DT-A/NLS/pGT5’/neo/pGT3’ vector contain positive-negative selection marker and NLS sequences in upstream of 5’ recombination arm which enhances nuclear transport of foreign DNA into bovine somatic cells. pGT5’/neo/pGT3’/NLS vector contain only positive selection marker and NLS sequence in downstream of 3’ recombination arm, not contain negative selectable marker. For transfection, linearzed vectors were introduced into porcine ear fibroblasts by electroporation. After 48 hours, the transfected cells were selected with 300 μg/ml G418 during 12 day. The G418-resistant colonies were picked, of which 5 colonies were positive for α1,3-GT gene disruption in 3´ PCR and southern blot screening. Three knock-out somatic cells were obtained from DT-A/NLS/ pGT5’/neo/pGT3’ knock-out vector. Thus, these data indicate that gene targeting vector using nuclear localization signal and negative selection marker improve targeting efficiency in porcine somatic cells.
본 연구는 돼지 정자의 동결 건조 시 동결 보호제인 trehalose의 효과와 동결 건조 시간과 동결 건조 후 저장 기간에 따라 정자의 생존성과 체외 성숙 난자 내 동결 건조 정자를 직접 주입한 후 전핵 형성율, 난할율 그리고 배발달 성적을 조사하였다. 동결 건조 후 정자의 생존율은 trehalose 무첨가구에 비해 trehalose를 첨가한 처리구에서 높은 생존율을 보였으며, 75 mM의 trehalose를 첨가하여 동결 건조한 정자들의 생존율이 가장 높은 것으로 나타났다. 또한, 동결 건조 후 저장 기간이 길어질수록 생존율이 낮아지는 경향이었다. 체외 성숙 난자 내 동결 건조 정자를 직접 주입 후 전핵 형성율은 trehalose 첨가구에서 유의적으로 높았으며(p<0.05), 난할율과 배발달 성적도 trehalose 첨가구에서 유의적으로 높았고(p<0.05), 정자의 동결 건조 시간이 짧을수록 높은 난할율과 배발달율을 보였다.