CRISPR/cas系统及其在家禽上的应用研究进展

CRISPR/cas是一种获得性免疫防御系统,广泛存在于细菌和古细菌中。Strep tococcus pyogenes cas9(Spcas9)作为目前研究最多、最清楚的效应蛋白,因其酶活性高和靶点广而被应用于生命科学各个领域,但Spcas9分子量大、脱靶率高等缺点在一定程度上限制了其应用。随着CRISPR系统技术被深入开发,一些新效应蛋白被发现,本文就CRISPR/cas系统分类、原理、新效应蛋白发现及cas9(S.Pyogenes)多种变构体技术开发在及家禽上的应用进行综述,为相关领域的研究提供参考。     

Improvements of TKC Technology Accelerate Isolation of Transgene-Free CRISPR/Cas9-Edited Rice Plants

Elimination of the CRISPR/Cas9 constructs in edited plants is a prerequisite for assessing genetic stability, conducting phenotypic characterization, and applying for commercialization of the plants. However, removal of the CRISPR/Cas9 transgenes by genetic segregation and by backcross is laborious and time consuming. We previously reported the development of the transgene killer CRISPR (TKC) technology that uses a pair of suicide genes to trigger self-elimination of the transgenes without compromising gene editing efficiency. The TKC technology enables isolation of transgene-free CRISPR-edited plants within a single generation, greatly accelerating crop improvements. Here, we presented two new TKC vectors that show great efficiency in both editing the target gene and in undergoing self-elimination of the transgenes. The new vectors replaced the CaMV35S promoter used in our previous TKC vector with two rice promoters to drive one of the suicide genes, providing advantages over our previous TKC vector under certain conditions. The vectors reported here offered more options and flexibility to conduct gene editing experiments in rice.     

利用CRISPR/Cas9系统编辑日本结缕草ZjSGR基因技术研究

日本结缕草(Zoysia japonica)是一种常见的具有众多优良性状的暖季型草种,秋冬季节在我国北方地区会较早出现叶片脱绿现象,在一定程度上限制了日本结缕草在北方的大面积使用。ZjSGR是从结缕草中分离出来的一种衰老诱导基因,负调控叶片滞绿性状。本研究利用CRISPR/Cas9系统,通过基因枪介导的遗传转化方法实现对日本结缕草ZjSGR基因的编辑,经测序验证获得1株单碱基缺失突变植株。突变植株叶片深绿,在正常生长温度(28~30℃)条件下,和对照相比,叶绿素含量更高(P<0.05)。本研究为进一步阐述ZjSGR基因在日本结缕草滞绿性状调控中的作用机理提供了基础研究材料,也为培育日本结缕草滞绿品种育种工作奠定了基础。     

Genome-edited crops: how to move them from laboratory to market

Recent breakthroughs in CRISPR technology allow specific genome manipulation of almost all crops and have initiated a revolution in precision crop breeding. Rationally-based regulation and widespread public acceptance are needed to propel genome-edited crops from laboratory to market and to translate this innovative technology into agricultural productivity.     

Reduction in cadmium accumulation in japonica rice grains by CRISPR/Cas9-mediated editing of OsNRAMP5

Cadmium (Cd) intake is harmful to human health and Cd contamination in rice grains represents a severe threat to those consuming rice as a staple food. Knockout of Cd transporters is a promising strategy to reduce Cd accumulation in rice grains. OsNRAMP5 is the major transporter for Cd and manganese (Mn) uptake in rice. Nevertheless, it is uncertain whether knockout of OsNRAMP5 is applicable to produce low Cd rice without affecting plant growth and grain yield. In this study, we adopted CRISPR/Cas9-based gene editing technology to knock out OsNRAMP5 in two japonica varieties. We generated three independent transgene-free osnramp5 mutants and investigated the effect of osnramp5 mutations on Cd accumulation and plant growth. Hydroponic experiments showed that plant growth and chlorophyll content were significantly reduced in osnramp5 mutants at low Mn conditions, and this defective growth in the mutants could be fully rescued by supply of high levels of Mn. Cd and Mn accumulation in both roots and shoots was markedly reduced in the mutants compared to that in wild-type plants. In paddy field experiments, although Cd in flag leaves and grains was greatly reduced in osnramp5 mutants, some agronomic traits including plant height, seed setting rate, and grain number per panicle were affected in the mutants, which ultimately caused a mild reduction in grain yield. The reduced plant growth in the mutants can be attributed to a marked decrease in Mn accumulation. Our results reveal that the manipulation of OsNRAMP5 should be treated with caution: When assessing the applicability of osnramp5 mutants, soil pH and soil water content in paddy fields need to be taken into consideration, since they might affect the levels of available Mn in the soil and consequently determine the effect of the mutation on grain yield.     

利用CRISPR/Cas9和λ-Red级联技术构建产肠毒素大肠杆菌LT敲除菌株

本研究旨在利用CRISPR/Cas9和λ-Red级联的技术对产肠毒素大肠杆菌（enterotoxigenic Escherichia coli，ETEC）K88的热不稳定性肠毒素（heat-labile toxin，LT）基因进行无痕敲除并获得K88 LT^-缺陷菌株。通过序列比对获取LT两端同源序列，并构建包含LT边界、氯霉素筛选标记、sgRNA和LT同源臂的供体片段；将供体片段转化至ETEC K88，同时分别利用λ-Red同源重组系统和CRISPR/Cas9基因编辑系统，对LT基因进行敲除；通过PCR验证获得了K88 LT^-缺陷菌株，并通过试验测定了敲除菌株的溶血能力和生长曲线。结果显示，λ-Red同源重组系统可成功地将LT基因替换为相应的供体片段，CRISPR/Cas9基因编辑系统可高效地对筛选标记进行删除，最终通过λ-Red和CRISPR/Cas9结合的基因编辑系统可成功对ETEC K88的LT基因进行无痕敲除。体外试验结果表明，K88 LT^-缺陷菌株的溶血能力丧失，并且生长速度比野生型菌株减缓，LT可能和ETEC K88的致病能力和生长性能有关。表明λ-Red和CRISPR/Cas9级联的基因敲除方法可用于LT毒素基因及其他一些大肠杆菌基因的敲除。K88 LT^-缺陷菌株的构建为下一步研究LT毒素的致病机制奠定基础。     

茶树咖啡碱合成酶CRISPR/Cas9基因组编辑载体的构建

CRISPR/Cas9技术是一门新兴的基因组定点编辑技术,具有操作简单、高效的优点,可轻松实现对目标基因的敲除、替换和定点突变等操作。该技术刚诞生,就受到了全球生命科学领域研究者的关注,不到3年的时间就已经成功应用于多种动、植物当中。然而CRISPR/Cas9技术在茶树中的应用面临载体构建问题,本文以茶树咖啡碱合成酶为例,联合采用常规PCR、Overlapping PCR和Golden Gate Cloning技术,构建了包含茶树咖啡碱合成酶双靶点的CRISPR/Cas9基因编辑载体,为CRISPR/Cas9介导的基因组编辑技术在茶树中的应用奠定了坚实基础。     

伪狂犬病病毒在NF-κB家族p65基因敲除细胞系的复制规律研究

试验旨在研究伪狂犬病病毒(PRV)在NF-κB家族p65基因敲除细胞系中的复制规律。利用慢病毒介导的CRISPR/Cas9基因定点修饰技术构建猪肺泡巨噬细胞(3D4/21)p65基因稳定敲除细胞系。通过构建p65-sgRNA重组质粒,转染至HEK293T/17细胞,收取慢病毒,感染3D4/21细胞后利用嘌呤霉素筛选获得多克隆细胞系,T7核酸酶检测敲除效率,再通过有限稀释法获得3D4/21-p65^-/-的稳定细胞系。CCK-8试剂盒检测3D4/21细胞中敲除p65基因后对细胞增殖的影响;流式细胞术检测PRV-GFP感染3D4/21及3D4/21-p65^-/-细胞后病毒增殖的差异;实时定量PCR检测PRV感染3D4/21及3D4/21-p65^-/-细胞后PRV gB、TK基因mRNA表达水平及PRV感染细胞诱导的IL-1β和IL-6基因mRNA水平表达的变化;Western blotting检测PRV-QXX感染3D4/21及3D4/21-p65^-/-细胞后PRV gB、gE蛋白的表达;滴度测定检测PRV-QXX感染3D4/21及3D4/21-p65^-/-细胞后子代病毒滴度。结果表明,sgRNA2和sgRNA3的基因编辑效率较高,对其进行克隆化培养进而获得敲除p65基因的稳定表达细胞系;CCK-8试剂盒检测细胞活力表明,p65基因敲除对细胞活力无影响;流式细胞仪检测表明,同一时间点PRV-GFP在3D4/21-p65^-/-中的增殖显著高于对照细胞;实时荧光定量PCR表明在3D4/21细胞中敲除p65基因促进了PRV gB、TK基因的mRNA表达水平,而抑制了IL-1β、IL-6基因的mRNA表达;Western blotting结果表明,在3D4/21细胞中敲除p65基因促进了PRV gB、gE蛋白的表达;滴度测定结果表明,同一时间点PRV-QXX在3D4/21-p65^-/-细胞中子代病毒的复制显著高于对照细胞。以上结果均表明,p65基因敲除可促进PRV在3D4/21细胞中复制。     

伪狂犬病病毒在NF-κB家族p65基因敲除细胞系的复制规律研究

试验旨在研究伪狂犬病病毒（PRV）在NF-κB家族p65基因敲除细胞系中的复制规律。利用慢病毒介导的CRISPR/Cas9基因定点修饰技术构建猪肺泡巨噬细胞（3D4/21）p65基因稳定敲除细胞系。通过构建p65-sgRNA重组质粒,转染至HEK293T/17细胞,收取慢病毒,感染3D4/21细胞后利用嘌呤霉素筛选获得多克隆细胞系,T7核酸酶检测敲除效率,再通过有限稀释法获得3D4/21-p65^-/-的稳定细胞系。CCK-8试剂盒检测3D4/21细胞中敲除p65基因后对细胞增殖的影响;流式细胞术检测PRV-GFP感染3D4/21及3D4/21-p65^-/-细胞后病毒增殖的差异;实时定量PCR检测PRV感染3D4/21及3D4/21-p65^-/-细胞后PRV gB、TK基因mRNA表达水平及PRV感染细胞诱导的IL-1β和IL-6基因mRNA水平表达的变化;Western blotting检测PRV-QXX感染3D4/21及3D4/21-p65^-/-细胞后PRV gB、gE蛋白的表达;滴度测定检测PRV-QXX感染3D4/21及3D4/21-p65^-/-细胞后子代病毒滴度。结果表明,sgRNA2和sgRNA3的基因编辑效率较高,对其进行克隆化培养进而获得敲除p65基因的稳定表达细胞系;CCK-8试剂盒检测细胞活力表明,p65基因敲除对细胞活力无影响;流式细胞仪检测表明,同一时间点PRV-GFP在3D4/21-p65^-/-中的增殖显著高于对照细胞;实时荧光定量PCR表明在3D4/21细胞中敲除p65基因促进了PRV gB、TK基因的mRNA表达水平,而抑制了IL-1β、IL-6基因的mRNA表达;Western blotting结果表明,在3D4/21细胞中敲除p65基因促进了PRV gB、gE蛋白的表达;滴度测定结果表明,同一时间点PRV-QXX在3D4/21-p65^-/-细胞中子代病毒的复制显著高于对照细胞。以上结果均表明,p65基因敲除可促进PRV在3D4/21细胞中复制。     

Embryo-mediated genome editing for accelerated genetic improvement of livestock

Selecting beneficial DNA variants is the main goal of animal breeding. However, this process is inherently inefficient because each animal only carries a fraction of all desirable variants. Genome editing technology with its ability to directly introduce beneficial sequence variants offers new opportunities to modernize animal breeding by overcoming this biological limitation and accelerating genetic gains. To realize rapid genetic gain, precise edits need to be introduced into genomically-selected embryos, which minimizes the genetic lag. However, embryo-mediated precision editing by homology-directed repair (HDR) mechanisms is currently an inefficient process that often produces mosaic embryos and greatly limits the numbers of available edited embryos. This review provides a summary of genome editing in bovine embryos and proposes an embryo-mediated accelerated breeding scheme that overcomes the present efficiency limitations of HDR editing in bovine embryos. It integrates embryo-based genomic selection with precise multi-editing and uses embryonic cloning with elite edited blastomeres or embryonic pluripotent stem cells to resolve mosaicism, enable multiplex editing and multiply rare elite genotypes. Such a breeding strategy would enable a more targeted, accelerated approach for livestock improvement that allows stacking of beneficial variants, even including novel traits from outside the breeding population, in the most recent elite genetic background, essentially within a single generation.