Chao Tianzhu, Liu Zhuangzhuang, Zhang Yu, Zhang Lichen, Huang Rong, He Le, Gu Yanrong, Chen Zhijun, Zheng Qianqian, Shi Lijin, Zheng Wenping, Qi Xinhui, Kong Eryan, Zhang Zhongjian, Lawrence Toby, Liang Yinming, Lu Liaoxun
Institute of Psychiatry and Neuroscience, Xinxiang Medical University, Xinxiang, China.
Henan Key Laboratory of Immunology and Targeted Therapy, School of Laboratory Medicine, Xinxiang Medical University, Xinxiang, China.
Front Genet. 2019 Feb 19;10:124. doi: 10.3389/fgene.2019.00124. eCollection 2019.
It is a tempting goal to identify causative genes underlying phenotypic differences among inbred strains of mice, which is a huge reservoir of genetic resources to understand mammalian pathophysiology. In particular, the wild-derived mouse strains harbor enormous genetic variations that have been acquired during evolutionary divergence over 100s of 1000s of years. However, validating the genetic variation in non-classical strains was extremely difficult, until the advent of CRISPR/Cas9 genome editing tools. In this study, we first describe a T cell phenotype in both wild-derived PWD/PhJ parental mice and F1 hybrids, from a cross to C57BL/6 (B6) mice, and we isolate a genetic locus on Chr2, using linkage mapping and chromosome substitution mice. Importantly, we validate the identification of the functional gene controlling this T cell phenotype, , by allele specific knockout of the PWD copy, leaving the B6 copy completely intact. Our experiments using F1 mice with a dominant phenotype, allowed rapid validation of candidate genes by designing sgRNA PAM sequences that only target the DNA of the PWD genome. We obtained 10 animals derived from B6 eggs fertilized with PWD sperm cells which were subjected to microinjection of CRISPR/Cas9 gene targeting machinery. In the newborns of F1 hybrids, 80% ( = 10) had allele specific knockout of the candidate gene of PWD origin, and no mice showed mistargeting of the B6 copy. In the resultant allele-specific knockout F1 mice, we observe full recovery of T cell phenotype. Therefore, our study provided a precise and rapid approach to functionally validate genes that could facilitate gene discovery in classic mouse genetics. More importantly, as we succeeded in genetic manipulation of mice, allele specific knockout could provide the possibility to inactivate disease alleles while keeping the normal allele of the gene intact in human cells.
识别近交系小鼠表型差异背后的致病基因是一个诱人的目标,近交系小鼠是理解哺乳动物病理生理学的巨大遗传资源库。特别是,野生来源的小鼠品系拥有在数万年的进化分歧过程中获得的巨大遗传变异。然而,在CRISPR/Cas9基因组编辑工具出现之前,验证非经典品系中的遗传变异极其困难。在本研究中,我们首先描述了野生来源的PWD/PhJ亲本小鼠及其与C57BL/6(B6)小鼠杂交产生的F1杂种的T细胞表型,并通过连锁图谱分析和染色体置换小鼠在2号染色体上分离出一个遗传位点。重要的是,我们通过对PWD拷贝进行等位基因特异性敲除,同时使B6拷贝完全保持完整,验证了控制这种T细胞表型的功能基因的鉴定。我们使用具有显性表型的F1小鼠进行实验,通过设计仅靶向PWD基因组DNA的sgRNA PAM序列,快速验证了候选基因。我们获得了10只由PWD精子细胞使B6卵子受精后经显微注射CRISPR/Cas9基因靶向机制产生的动物。在F1杂种的新生小鼠中,80%(n = 10)具有PWD来源候选基因的等位基因特异性敲除,没有小鼠出现对B6拷贝的靶向错误。在所得的等位基因特异性敲除F1小鼠中,我们观察到T细胞表型完全恢复。因此,我们的研究提供了一种精确且快速的方法来功能验证基因,这有助于在经典小鼠遗传学中发现基因。更重要的是,由于我们成功地对小鼠进行了基因操作,等位基因特异性敲除可以提供在人类细胞中使疾病等位基因失活同时保持该基因正常等位基因完整的可能性。
