Approaches for the sensitive detection of rare base and prime editing events

Approaches for the sensitive detection of rare base and prime editing events

•Novel, agarose gel-based detection methods for base and prime editing detection.•Workflow from transfection through to analysis for base and prime editing.•Base editing of plasmid DNA targets in mammalian cells. Precision chemistry entailing user-directed nucleotide substitutions and template-speci...

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Veröffentlicht in:Methods (San Diego, Calif.) Calif.), 2021-10, Vol.194, p.75-82
Hauptverfasser: Nguyen Tran, Minh Thuan, Rajendra, K.C., Patterson, Freya M., Liu, Guei-Sheung, Cook, Anthony L., Hewitt, Alex W.
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ARMS
Base editing
Biochemical Research Methods
Biochemistry & Molecular Biology
Detection
DNA
Gene Editing
Genome
Genomics
High throughput
Life Sciences & Biomedicine
Polymerase Chain Reaction
Polymorphism, Restriction Fragment Length
Prime editing
RFLP
Science & Technology
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container_end_page 82
container_issue
container_start_page 75
container_title Methods (San Diego, Calif.)
container_volume 194
creator Nguyen Tran, Minh Thuan
Rajendra, K.C.
Patterson, Freya M.
Liu, Guei-Sheung
Cook, Anthony L.
Hewitt, Alex W.
description •Novel, agarose gel-based detection methods for base and prime editing detection.•Workflow from transfection through to analysis for base and prime editing.•Base editing of plasmid DNA targets in mammalian cells. Precision chemistry entailing user-directed nucleotide substitutions and template-specified repair can be facilitated by base editing and prime editing, respectively. Recently, the diversification of adenine, cytosine, and prime editor variants obliges a considered, high-throughput evaluation of these tools for optimized, end-point applications. Herein, we outline novel, cost-effective and scalable approaches for the rapid detection of base editing and prime editing outcomes using gel electrophoresis. For base editing, we exploit primer mismatch amplification (SNP genotyping) for the gel-based detection of base editing efficiencies as low as 0.1%. For prime editing, we describe a one-pot reaction combining polymerase chain reaction (PCR) amplification of the target region with restriction digestion (restriction fragment length polymorphism; RFLP). RFLP enables the rapid detection of insertion or deletion events in under 2.5 h from genomic DNA extraction. We show that our method of SNP genotyping is amenable to both endogenous target loci as well as transfected, episomal plasmid targets in BHK-21 cells. Next, we validate the incidence of base and prime editing by describing Sanger sequencing and next-generation sequencing (NGS) workflows for the accurate validation and quantification of on-target editing efficiencies. Our workflow details three different methods for the detection of rare base and prime editing events, enabling a tiered approach from low to high resolution that makes use of gel electrophoresis, Sanger sequencing, and NGS.
doi_str_mv 10.1016/j.ymeth.2021.01.006
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subjects ARMS
Base editing
Biochemical Research Methods
Biochemistry & Molecular Biology
Detection
DNA
Gene Editing
Genome
Genomics
High throughput
Life Sciences & Biomedicine
Polymerase Chain Reaction
Polymorphism, Restriction Fragment Length
Prime editing
RFLP
Science & Technology
title Approaches for the sensitive detection of rare base and prime editing events
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