利用2细胞(2C)-同源重组(HR)-CRISPR高效生成大片段敲入小鼠模型

Q1 Agricultural and Biological Sciences Current protocols in mouse biology Pub Date : 2020-01-08 DOI:10.1002/cpmo.67

Bin Gu, Eszter Posfai, Marina Gertsenstein, Janet Rossant

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引用次数: 26

摘要

直接在小鼠胚胎中产生大片段敲入基因，如报告基因、条件等位基因或人源化等位基因，仍然是一项具有挑战性的壮举。我们已经开发了2C-HR-CRISPR，这项技术可以高效(10-50%)和快速(在2个月内产生创始人)靶向大的DNA片段。该策略的关键是将CRISPR试剂输送到2细胞期小鼠胚胎中，利用这一阶段长G2细胞周期阶段的高同源重组活性。此外，利用cas9单体链亲和素(cas9 - streptavidin, Cas-mSA)和生物素化PCR模板(BioPCR)系统将修复模板定位到特定的双链断裂，效率可进一步提高到95%。在这里，我们提供了一种使用2C-HR-CRISPR生成大片段敲入小鼠模型的程序。我们首先描述了设计单导rna和修复模板的原则，但参考了分子克隆方法或这些试剂的商业来源的已发表的手稿和协议。然后，我们描述了2C-HR-CRISPR的两个对成功至关重要的独特方面:(1)生产用于2C-HR-CRISPR的CRISPR试剂，特别是应用Cas9-mSA/BioPCR方法;(2)在2细胞阶段对小鼠胚胎进行显微注射。©2020 by John Wiley &基本方案1:单导RNA和修复模板设计。基本方案2:制备2c - hr - crispr试剂。基本方案3:微注射2细胞期小鼠胚胎

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Efficient Generation of Large-Fragment Knock-In Mouse Models Using 2-Cell (2C)-Homologous Recombination (HR)-CRISPR

Generating large-fragment knock-ins, such as reporters, conditional alleles, or humanized alleles, directly in mouse embryos is still a challenging feat. We have developed 2C-HR-CRISPR, a technology that allows highly efficient (10-50%) and rapid (generating founders in 2 months) targeting of large DNA fragments. Key to this strategy is the delivery of CRISPR reagents into 2-cell-stage mouse embryos, taking advantage of the high homologous recombination activity during the long G₂ cell cycle phase at this stage. Furthermore, by exploiting a Cas9–monomeric streptavidin (Cas-mSA) and biotinylated PCR template (BioPCR) system to localize the repair template to specific double strand breaks, the efficiency can be further improved to up to 95%. Here we provide a procedure to generate large-fragment knock-in mouse models using 2C-HR-CRISPR. We first describe the principles for designing single guide RNAs and repair templates but refer to published manuscripts and protocols for molecular cloning methods or commercial sources for these reagents. We then describe two unique aspects of 2C-HR-CRISPR that are critical for success: (1) production of the CRISPR reagents for 2C-HR-CRISPR, particularly for applying the Cas9-mSA/BioPCR method, and (2) microinjection of mouse embryos at the 2-cell stage. © 2020 by John Wiley & Sons, Inc.

Basic Protocol 1: Single guide RNA and repair template design

Basic Protocol 2: Preparing reagents for 2C-HR-CRISPR

Basic Protocol 3: Microinjecting 2-cell-stage mouse embryos

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Current protocols in mouse biology Agricultural and Biological Sciences-Animal Science and Zoology

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期刊介绍： Sound and reproducible laboratory methods are the foundation of scientific discovery. Yet, all too often, nuances that are critical for an experiment''s success are not captured in the primary literature but exist only as part of a lab''s oral tradition. The aim of Current Protocols in Mouse Biology is to provide the clearest, most detailed and reliable step-by-step instructions for protocols involving the use of mice in biomedical research. Written by experts in the field and extensively edited to our exacting standards, the protocols include all of the information necessary to complete an experiment in the laboratory—introduction, materials lists with supplier information, detailed step-by-step procedures with helpful annotations, recipes for reagents and solutions, illustrative figures and information-packed tables. Each article also provides invaluable discussions of background information, applications of the methods, important assumptions, key parameters, time considerations, and tips to help avoid common pitfalls and troubleshoot experiments. Furthermore, Current Protocols in Mouse Biology content is thoughtfully organized by topic for optimal usage and to maximize contextual knowledge. Quarterly issues allow Current Protocols to constantly evolve to keep pace with the newest discoveries and developments. Current Protocols in Mouse Biology brings together resources in mouse biology and genetics and provides a mouse protocol resource that covers all aspects of mouse biology. Current Protocols in Mouse Biology also permits optimization of mouse model usage, which is significantly impacted by both cost and ethical constraints. Optimal and standardized mouse protocols ultimately reduce experimental variability and reduce the number of animals used in mouse experiments.