UDiTaS™, a Genome Editing Detection Method for Indels and Genome Rearrangements

Overview

Journal BMC Genomics

Publisher Biomed Central

Specialty Genetics

Date 2018 Mar 23

PMID 29562890

Citations 73

Authors

Georgia Giannoukos

Dawn M Ciulla

Eugenio Marco

Hayat S Abdulkerim

Luis A Barrera

Anne Bothmer

Vidya Dhanapal

Sebastian W Gloskowski

Hariharan Jayaram

Morgan L Maeder

Maxwell N Skor

Tongyao Wang

Vic E Myer

Christopher J Wilson

Affiliations

Soon will be listed here.

Abstract

Background: Understanding the diversity of repair outcomes after introducing a genomic cut is essential for realizing the therapeutic potential of genomic editing technologies. Targeted PCR amplification combined with Next Generation Sequencing (NGS) or enzymatic digestion, while broadly used in the genome editing field, has critical limitations for detecting and quantifying structural variants such as large deletions (greater than approximately 100 base pairs), inversions, and translocations.

Results: To overcome these limitations, we have developed a Uni-Directional Targeted Sequencing methodology, UDiTaS, that is quantitative, removes biases associated with variable-length PCR amplification, and can measure structural changes in addition to small insertion and deletion events (indels), all in a single reaction. We have applied UDiTaS to a variety of samples, including those treated with a clinically relevant pair of S. aureus Cas9 single guide RNAs (sgRNAs) targeting CEP290, and a pair of S. pyogenes Cas9 sgRNAs at T-cell relevant loci. In both cases, we have simultaneously measured small and large edits, including inversions and translocations, exemplifying UDiTaS as a valuable tool for the analysis of genome editing outcomes.

Conclusions: UDiTaS is a robust and streamlined sequencing method useful for measuring small indels as well as structural rearrangements, like translocations, in a single reaction. UDiTaS is especially useful for pre-clinical and clinical application of gene editing to measure on- and off-target editing, large and small.

Citing Articles

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