Abstract

CRISPR-associated nucleases are powerful tools for precise genome editing of model systems, including human organoids. Current methods describing fluorescent gene tagging in organoids rely on the generation of DNA double-strand breaks (DSBs) to stimulate homology-directed repair (HDR) or non-homologous end joining (NHEJ)-mediated integration of the desired knock-in. A major downside associated with DSB-mediated genome editing is the required clonal selection and expansion of candidate organoids to verify the genomic integrity of the targeted locus and to confirm the absence of off-target indels. By contrast, concurrent nicking of the genomic locus and targeting vector, known as in-trans paired nicking (ITPN), stimulates efficient HDR-mediated genome editing to generate large knock-ins without introducing DSBs. Here, we show that ITPN allows for fast, highly efficient, and indel-free fluorescent gene tagging in human normal and cancer organoids. Highlighting the ease and efficiency of ITPN, we generate triple fluorescent knock-in organoids where 3 genomic loci were simultaneously modified in a single round of targeting. In addition, we generated model systems with allele-specific readouts by differentially modifying maternal and paternal alleles in one step. ITPN using our palette of targeting vectors, publicly available from Addgene, is ideally suited for generating error-free heterozygous knock-ins in human organoids.

Highlights

  • Since the development of efficient genome editing technology, molecular and cell biological research increasingly relies on genetically modified in vitro model systems

  • To stimulate editing via non-homologous end joining (NHEJ)-mediated ligation of a linearized mScarlet-coding fragment into the Cas9-generated genomic double-strand break (DSB) [6,7], we constructed a vector carrying the mScarlet-coding sequence flanked by copies of the genomic Cas9 target site

  • We generated vectors with 1 kb homology arms following a traditional targeting vector design that is without flanking Cas9 target sites, or with flanking Cas9 target sites to support genomic integration via in-trans paired nicking (ITPN) or in-trans paired cleavage (ITPC) [14,15]

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Summary

Introduction

Since the development of efficient genome editing technology, molecular and cell biological research increasingly relies on genetically modified in vitro model systems. The visualization of endogenous proteins using fluorescent knock-in reporters allows for a precise assessment of their subcellular localization and dynamics during cellular homeostasis and disease [1]. Error-free CRISPR knock-ins in human organoids using Cas nickase files. All algorithms used for the mapping [gatk. Broadinstitute.org], mutational calling [https:// github.com/ToolsVanBox/NF-IAP], and filtering of mutations [https://github.com/ToolsVanBox/ SMuRF, https://github.com/hartwigmedical/gridsspurple-linx] are publicly available. Raw FCS files are available on the FlowRepository database (flowrepository.org) and accessible using the repository ID FR-FCM-Z4PJ

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