Cas9-expressing cattle using the PiggyBac transposon all-in-one system.

IF 3.7 2区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY BMC Genomics Pub Date : 2025-03-05 DOI:10.1186/s12864-025-11381-8

Dong-Hyeok Kwon, Gyeong-Min Gim, Soo-Young Yum, Kyeong-Hyeon Eom, Song-Jeon Lee, Sang-Eun Han, Hee-Soo Kim, Hyeong-Jong Kim, Woo-Sung Lee, Woo-Jae Choi, Ji-Hyun Lee, Do-Yoon Kim, Dae-Jin Jung, Dae-Hyun Kim, Jun-Koo Yi, Byeong-Ho Moon, Won-You Lee, Goo Jang

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Abstract

Background: Livestock, particularly cattle, are crucial for biotechnology fields, such as genetic breeding, infectious diseases, bioreactors, and specific disease models. However, genetic engineering in cattle has lagged due to long gestation periods, single embryo pregnancies, and high rearing costs. Additionally, the slow validation of germline transmission and the absence of germline-competent embryonic stem cells hinder progress. With the development of genome editing technologies like ZFN, TALEN, and CRISPR-Cas9, recent advancements have shown that Cas9-expressing pigs and chickens have been successfully produced. We hypothesize that generating CRISPR/Cas9-expressing cattle and their resources will provide a powerful resource for bovine genome editing, advancing our understanding of bovine genetics and disease resistance.

Results: In this study, two types of Cas9-expressing cattle were successfully produced: Cas9-RFP-fatty acid dehydrogenase I (FatI), Cas9-GFP-sgRNA for the prion protein (sgPRNP). Somatic cells from these cattle were induced to mutate multiple target genes when single-guide RNAs (sgRNAs) were transfected into the somatic cells. Additionally, semen from Cas9 expressing male cattle was frozen and used to fertilize wild-type oocytes, successfully transmitting the transgene (Cas9, reporter genes, FatI), and sgPRNP) to the next generation. Furthermore, the gene editing capabilities of Cas9, including knockout and high-efficiency knock-in, were confirmed in embryos derived from F1 semen through in vitro production.

Conclusion: These data demonstrate, for the first time, that Cas9-expressing cattle were successfully born, and this transgene was transmitted to the next-generation calves (F1) and F2 embryos. In addition, somatic and germ cells derived from F0 and F1generations were used to evaluate the potential for gene editing (knockout and knock-in) in multiple genes. PRNP-mutated F1 cattle are currently being raised as a resistance model for bovine spongiform encephalopathy. These transgenic bovine models and their derivatives will serve as a valuable resource for both in vitro and in vivo genome editing, advancing our genetic understanding of bovine genomics and diseases.

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使用PiggyBac转座子一体化系统表达cas9的牛。

背景：牲畜，特别是牛，对遗传育种、传染病、生物反应器和特定疾病模型等生物技术领域至关重要。然而，由于妊娠期长、单胚胎妊娠和饲养成本高，牛的基因工程一直滞后。此外，生殖系传播的缓慢验证和缺乏生殖系胜任的胚胎干细胞阻碍了进展。随着ZFN、TALEN和CRISPR-Cas9等基因组编辑技术的发展，最近的进展表明，已经成功生产出表达cas9的猪和鸡。我们假设，产生表达CRISPR/ cas9的牛及其资源将为牛基因组编辑提供强大的资源，促进我们对牛遗传学和抗病的理解。结果：本研究成功培育出两种cas9表达牛：cas9 - rfp -脂肪酸脱氢酶I （FatI）、cas9 - gfp -朊蛋白sgrna （sgPRNP）。将单导rna （single-guide RNAs, sgRNAs）转染到这些牛的体细胞中，诱导多个靶基因发生突变。此外，将表达Cas9的雄性牛的精液冷冻并用于使野生型卵母细胞受精，成功地将转基因（Cas9、报告基因、FatI）和sgPRNP传递给下一代。此外，Cas9的基因编辑能力，包括敲除和高效敲入，已在通过体外生产的F1精液衍生的胚胎中得到证实。结论：这些数据首次证明表达cas9的牛成功出生，并将该转基因传递给下一代小牛（F1）和F2胚胎。此外，来自F0和f1代的体细胞和生殖细胞被用于评估多个基因基因编辑（敲除和敲入）的潜力。目前正在饲养prnp突变的F1牛，作为牛海绵状脑病的抗性模型。这些转基因牛模型及其衍生物将成为体外和体内基因组编辑的宝贵资源，促进我们对牛基因组学和疾病的遗传理解。

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来源期刊

BMC Genomics 生物-生物工程与应用微生物

CiteScore

7.40

自引率

4.50%

发文量

769

审稿时长

6.4 months

期刊介绍： BMC Genomics is an open access, peer-reviewed journal that considers articles on all aspects of genome-scale analysis, functional genomics, and proteomics. BMC Genomics is part of the BMC series which publishes subject-specific journals focused on the needs of individual research communities across all areas of biology and medicine. We offer an efficient, fair and friendly peer review service, and are committed to publishing all sound science, provided that there is some advance in knowledge presented by the work.