Efficient Gene Knockout in Goats Using CRISPR/Cas9 System

The CRISPR/Cas9 system has been adapted as an efficient genome editing tool in laboratory animals such as mice, rats, zebrafish and pigs. Here, we report that CRISPR/Cas9 mediated approach can efficiently induce monoallelic and biallelic gene knockout in goat primary fibroblasts. Four genes were disrupted simultaneously in goat fibroblasts by CRISPR/Cas9-mediated genome editing. The single-gene knockout fibroblasts were successfully used for somatic cell nuclear transfer (SCNT) and resulted in live-born goats harboring biallelic mutations. The CRISPR/Cas9 system represents a highly effective and facile platform for targeted editing of large animal genomes, which can be broadly applied to both biomedical and agricultural applications.     

基因编辑技术在斑马鱼中的应用及研究进展

基因编辑技术通过对特定DNA片段的插入、敲除、修饰或替换等,实现对生物体中目标基因的编辑。与早期基因工程技术将遗传物质随机插入宿主基因组中的方式不同的是,基因编辑技术能够定点需要插入的位置,从而实现对生物体基因组特定位点的准确修饰、人为地改造生物体的遗传信息,目前广泛应用于斑马鱼的基因组学、遗传发育和基因功能研究中。其方法包括诱变技术、Tol2转座子、Morpholino、ZFNs、TALEN和CRISPR/Cas系统等。本研究主要介绍了基因编辑技术的作用机理与发展概况。作为一种精准而高效的基因工程方法,基因编辑技术在近年来得到了飞速地发展。它既可以采用对特定基因的靶向突变来研究基因的功能,也可以通过将功能性基因插入并替代缺陷基因而用于某些遗传性疾病的基因治疗。可以肯定的是,基因编辑技术未来将在基础生物学、医学、生物技术等多个领域具有重要的研究价值和应用价值。     

利用CRISPR/Cas9系统构建Tiki1基因修饰猪模型

Tiki1基因是哈佛大学儿童医学院贺熹教授实验室发现的一个对蛙头部的诱导起到决定性作用的新基因,但Tiki1基因在小鼠等啮齿类动物中缺失,因此无法利用小鼠等小动物来研究其在哺乳动物中的作用.本文利用CRISPR/Cas9系统结合体细胞克隆技术构建Tiki1基因修饰猪模型,研究Tiki1基因在猪发育中的作用.我们利用贺熹教授团队提供的人Tiki1基因序列,在猪的基因组数据库中比对出与其同源性最高的一段序列设计2个靶位点(g1和g2).以设计的靶位点构建打靶质粒转染猪胎儿成纤维细胞,经细胞筛选、PCR扩增及测序共鉴定了52个单细胞克隆株.最终选择靶位点g1为纯合双敲的5个单细胞克隆株和靶位点g2为纯合双敲的3个单细胞克隆株作为构建Tiki1基因敲除猪的核供体.我们共计构建了720个重组胚胎,分别植入3头代孕母猪,其中有1头经B超检测成功怀孕并妊娠到期产下13头发育正常的克隆猪,经测序鉴定其中12头为Tiki1基因双敲除猪模型,Tiki1基因敲除克隆猪健康存活至今.结果表明Tiki1基因对于猪早期发育的作用机理不同于蛙,其在猪早期发育的过程中的具体作用机理有待后续进一步的深入研究.     

Efficient biallelic mutagenesis with Cre/loxP-mediated inter-chromosomal recombination

The isolation of mutant cells with phenotypes caused by random mutagenesis has been hampered in mammalian cells because there are two alleles per gene and the disruption of both alleles is extremely rare. We describe a method for the efficient biallelic mutagenesis in embryonic stem cells. loxP sites were introduced near the centromeric regions of a pair of chromosome 1s. A mutant neo gene was inserted at the distal part of one of the loxP sites so that biallelic mutants would be selected by high-dose G418. Expression of Cre induced the recombination between homologous chromosomes and led to an elevation in the number of biallelic mutants. This system will facilitate phenotype-driven gene function study in the mammalian system.     

Optimized TAL effector nucleases (TALENs) for use in treatment of sickle cell disease

TAL effector nucleases (TALENs) represent a new class of artificial nucleases capable of cleaving long, specific target DNA sequences in vivo and are powerful tools for genome editing with potential therapeutic applications. Here we report a pair of custom-designed TALENs for targeted genetic correction of the sickle cell disease mutation in human cells, which represents an example of engineered TALENs capable of recognizing and cleaving a human disease-associated gene. By using a yeast reporter system, a systematic study was carried out to optimize TALEN architecture for maximal in vivo cleavage efficiency. In contrast to the previous reports, the engineered TALENs were capable of recognizing and cleaving target binding sites preceded by A, C or G. More importantly, the optimized TALENs efficiently cleaved a target sequence within the human β-globin (HBB) gene associated with sickle cell disease and increased the efficiency of targeted gene repair by >1000-fold in human cells. In addition, these TALENs showed no detectable cytotoxicity. These results demonstrate the potential of optimized TALENs as a powerful genome editing tool for therapeutic applications.     

The Position of DNA Cleavage by TALENs and Cell Synchronization Influences the Frequency of Gene Editing Directed by Single-Stranded Oligonucleotides

With recent technological advances that enable DNA cleavage at specific sites in the human genome, it may now be possible to reverse inborn errors, thereby correcting a mutation, at levels that could have an impact in a clinical setting. We have been developing gene editing, using single-stranded DNA oligonucleotides (ssODNs), as a tool to direct site specific single base changes. Successful application of this technique has been demonstrated in many systems ranging from bacteria to human (ES and somatic) cells. While the frequency of gene editing can vary widely, it is often at a level that does not enable clinical application. As such, a number of stimulatory factors such as double-stranded breaks are known to elevate the frequency significantly. The majority of these results have been discovered using a validated HCT116 mammalian cell model system where credible genetic and biochemical readouts are available. Here, we couple TAL-Effector Nucleases (TALENs) that execute specific ds DNA breaks with ssODNs, designed specifically to repair a missense mutation, in an integrated single copy eGFP gene. We find that proximal cleavage, relative to the mutant base, is key for enabling high frequencies of editing. A directionality of correction is also observed with TALEN activity upstream from the target base being more effective in promoting gene editing than activity downstream. We also find that cells progressing through S phase are more amenable to combinatorial gene editing activity. Thus, we identify novel aspects of gene editing that will help in the design of more effective protocols for genome modification and gene therapy in natural genes.     

TALEN‐mediated targeted mutagenesis produces a large variety of heritable mutations in rice

CRISPR/Cas9 and TALEN are currently the two systems of choice for genome editing. We have studied the efficiency of the TALEN system in rice as well as the nature and inheritability of TALEN‐induced mutations and found important features of this technology. The N287C230 TALEN backbone resulted in low mutation rates (0–6.6%), but truncations in its C‐terminal domain dramatically increased efficiency to 25%. In most transgenic T0 plants, TALEN produced a single prevalent mutation accompanied by a variety of low‐frequency mutations. For each independent T0 plant, the prevalent mutation was present in most tissues within a single tiller as well as in all tillers examined, suggesting that TALEN‐induced mutations occurred very early in the development of the shoot apical meristem. Multigenerational analysis showed that TALEN‐induced mutations were stably transmitted to the T1 and T2 populations in a normal Mendelian fashion. In our study, the vast majority of TALEN‐induced mutations (~81%) affected multiple bases and ~70% of them were deletions. Our results contrast with published reports for the CRISPR/Cas9 system in rice, in which the predominant mutations affected single bases and deletions accounted for only 3.3% of the overall mutations.