Programmable gene insertion in human cells with a laboratory-evolved CRISPR-associated transposase
Broad Institute · Howard Hughes Medical Institute · +3 more institutions
Abstract
Programmable gene integration in human cells has the potential to enable mutation-agnostic treatments for loss-of-function genetic diseases and facilitate many applications in the life sciences. CRISPR-associated transposases (CASTs) catalyze RNA-guided DNA integration but thus far demonstrate minimal activity in human cells. Using phage-assisted continuous evolution (PACE), we generated CAST variants with >200-fold average improved integration activity. The evolved CAST system (evoCAST) achieves ~10 to 30% integration efficiencies of kilobase-size DNA cargoes in human cells across 14 tested genomic target sites, including safe harbor loci, sites used for immunotherapy, and genes implicated in loss-of-function…
Citation impact
- FWCI
- 42.13
- Percentile
- 100%
- References
- 129
Authors
15- IPIsaac P. WitteCorresponding
Broad Institute, Howard Hughes Medical Institute, Harvard University
- GDGeorge D. LampeCorresponding
Howard Hughes Medical Institute, Columbia University
- SESimon EitzingerCorresponding
Broad Institute, Howard Hughes Medical Institute, Harvard University
- SMShannon M. Miller
Broad Institute, Howard Hughes Medical Institute, Harvard University
- KNKiara N. Berríos
Broad Institute, Howard Hughes Medical Institute, Harvard University
Topics & keywords
- Transposase
- CRISPR
- Biology
- Transposable element
- Computational biology
- Gene
- Genetics
- Genome