ABSTRACT
The CRISPR/Cas9 system is widely used to permanently delete genomic regions by inducing double-strand breaks via dual guide RNAs. However, on-target consequences of Cas9 deletion events have yet to be fully investigated. To characterize Cas9-induced genotypic abnormalities in human cells, we utilized an innovative droplet-based target enrichment approach followed by long-read sequencing and coupled it to a customized de novo sequence assembly. This approach enabled us to dissect the sequence content at kilobase scale within an on-target genomic locus. We here describe extensive genomic disruptions by Cas9, involving a genomic duplication and inversion of the target region as well as integrations of exogenous DNA and interchromosomal DNA fragment rearrangements at the double-strand break sites often at the same time. Although these events altered the genomic composition of the on-target region, we found that the aberrant DNA fragments are still functional, marked by active histones and bound by RNA polymerase III. In HAP1 cells, the integration of the target-derived fragments accelerated cell proliferation in deletion clones. Our findings broaden the consequential spectrum of the Cas9 deletion system, reinforce the necessity of meticulous genomic validations and rationalize extra caution when interpreting results from a deletion event.
Competing Interest Statement
The authors have declared no competing interest.
LIST OF ABBREVIATIONS
- Δt
- tRNA gene locus deletion
- Δi
- intergenic region deletion
- BP
- breakpoint
- Cas9
- CRISPR-associated protein 9
- CRISPR
- clustered regularly interspaced short palindromic repeats
- ctrl
- non-targeting control
- DC
- daughter cell
- dMDA
- droplet multiple displacement amplification
- DSB
- double-strand break
- E. coli
- Escherichia coli
- gRNA
- guide RNA
- H3K4me3
- histone 3 lysine 4 trimethylation
- HAP1
- chronic myeloid leukemia cell line
- HepG2
- hepatocellular carcinoma
- LRS
- long-read sequencing
- MMEJ
- microhomology-mediated end joining
- NHEJ
- nonhomologous end joining
- nt
- non-transfected control
- ONT
- Oxford Nanopore Technology
- PAM
- protospacer adjacent motif
- Pol III
- RNA polymerase III
- tRNA
- transfer RNA