배스(Micropterus salmoides)는 수생태계에서 최상위단계에 위치하는 생태계교란 어종으로 심각한 담수생태계의 불균형을 초래하고 있다. 배스의 퇴치 및 관리를 위한 다양한 시도를 하고 있지만 효과적인 방안은 없는 상황이므로 배스의 고유한 특성에 기반한 개체군 감소의 효율성을 극대화할 수 있는 방식을 모색하였다. 본 연구에서는 배스의 Transcriptom 분석으로 Unigene contigs는 182,887개, 그리고 정자-난자 인식 단백질인 IZUMO1과 Zona pellucida sperm-binding protein의 유전자에서 CRISPR/Cas9 system을 적용할 최종 Target sequence는 12종을 산출하였다. 각 Target sequence를 인식할 수 있는 12종의 sgRNA를 합성한 후 후속 연구에 사용할 12종의 Cas9-sgRNA ribonucleoprotein (RNP) complex를 제작하였다. 본 연구에서는 차세대염기서열 분석법으로 정자-난자 인식 단백질을 암호화하는 유전자를 탐색하였고, CRISPR/Cas9 system으로 유전자를 편집하여 번식행동은 하지만 수정란을 형성하지 못하는 생식세포를 생산하는 불임개체를 유도하기 위한 조성물 개발 과정을 확립하였다. 그리고 배스와 동일한 수계에 있는 고유 생물종의 서식에는 영향을 미치지 않는 생태교란종 관리 방안으로서의 유용성을 검증하기 위한 후속 연구의 귀중한 기초 자료를 확보하는데 기여했다고 판단된다.
Pigs are considered as optimal donor animal for the successful xenotransplantation. To increase the possibility of clinical application, genetic modification to increase compatibility with human is an important and essential process. Genetic modification technique has been developed and improved to produce genetically modified pigs rapidly. CRISPR/Cas9 system is widely used in various fields including the production of transgenic animals and also can be enable multiple gene modifications. In this study, we developed new gene targeting vector and enrichment system for the rapid and efficient selection of genetically modified cells. We conducted co-transfection with two targeting vectors for simultaneous inactivation of two genes and enrichment of the genetically modified cells using MACS. After this efficient enrichment, genotypic analysis of each colony showed that colonies which have genetic modifications on both genes were confirmed with high efficiency. Somatic cell nuclear transfer was conducted with established donor cells and genetically modified pigs were successfully produced. Genotypic and phenotypic analysis of generated pigs showed identical genotypes with donor cells and no surface expression of α-Gal and HD antigens. Furthermore, functional analysis using pooled human serum revealed dramatically reduction of human natural antibody (IgG and IgM) binding level and natural antibody-mediated cytotoxicity. In conclusion, the constructed vector and enrichment system using MACS used in this study is efficient and useful to generate genetically modified donor cells with multiple genetic alterations and lead to an efficient production of genetically modified pigs.
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).
CRISPRs(clustered regularly interspaced short palindromic repeats) / CRISPR - associated(CAS) system has been used genome editing technology. Genome stage modification using CRISPR/CAS9 system can be used to wide research for the gene functional study and therapeutics. However, improving of CRISPR/CAS9 system in efficiency is essential for application in various fields. Here, we treated various chemicals during the procine early embryo development to increase the mutation of target site by NHEJ(non-homologous end joining). Firstly, we confirmed the chemical toxicity after parthenogenetic activation and then check embryo puality using by counting of total cell number and TUNEL Assay in blastocyst satge. To check any improvement on mutation rate by NHEJ pathway. AZT(3′-Azido-3′-deoxythymidine, antiretroviral drug – 0.1 μM) was treated after injection of cas9 and sgRNA target to OCT4 exon 5 during the zygote stage, followed by PCR sequencing. As a result, AZT treated group shows a significantly increased in knock-out efficiency as a consequence of NHEJ. Nocodazole(anti-neoplastic agent – 200ng/ml), RO-3306 (specific inhibitor of CDK1 - 10 μM) and NU-7026(PKC signalling inhibitor - 50 μM) was treated after injection of cas9 and sgRNA with eGFP vector during the zygote stage(hpa8~hpa20) and checked a efficiency of knock-in by PCR sequencing. Interestingly, nocodazole treatment groups increased of insertion of eGFP sequence in blastocyst stage compared with non-treat group(control : 8.33%, nocodazole treatment : 16.67%). However, RO-3306 and NU-7026 made a no impact. In summary, CRISPR/CAS9 system with treatment of chemicals during porcine embryogenesis can be improving of site-specific mutation and enhancement of CRISPR genome editing.
The clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR associated protein (Cas9) system can be applied to produce transgenic pigs. Therefore, we applied CRISPR/Cas9 system to generate FoxN1-targeted pig parthenogenetic embryos. Using single guided RNA targeted to pig FoxN1 genes was injected into cytoplasm of in vitro matured oocyte before electrical activation. In results, regardless of the concentrations of vector, the cleavage rate were significantly (p<0.05) decreased (4 ng/μl, 51.24%; 8 ng/μl, 40.88%; and 16 ng/μl; 45.22%) compared to no injection group (70.44%). The blastocyst formation rates were also decreased in vector injected 3 groups (4 ng/μl, 7.96%; 8 ng/μl, 6.4%; and 16 ng/μl; 9.04%) compared to no injection group (29.07%). In addition, the blastocyst formation rates between sham injected group (13.51%) and no injection group (29.07%) also showed significant difference (p<0.05). The mutation rates were comparable between groups (4 ng/μl, 18.4%; 8 ng/μl, 12.5%; and 16 ng/μl; 20.0%). The sequencing analysis showed that blastocysts derived from each group were successfully mutated in FoxN1 loci regardless of the vector concentrations. However, the deletion patterns were higher than the patterns of point mutation and insertion regardless of the vector concentrations. In conclusion, we described that cytoplasmic microinjection of FoxN1-targeted CRISPR/Cas9 vector could efficiently generate transgenic pig parthenogenetic embryos in one-step.