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Literature DB >> 31740839

Harnessing type I CRISPR-Cas systems for genome engineering in human cells.

Peter Cameron¹, Mary M Coons², Sanne E Klompe^2,3, Alexandra M Lied², Stephen C Smith², Bastien Vidal², Paul D Donohoue², Tomer Rotstein^2,4, Bryan W Kohrs², David B Nyer², Rachel Kennedy^2,5, Lynda M Banh², Carolyn Williams², Mckenzi S Toh², Matthew J Irby², Leslie S Edwards², Chun-Han Lin², Arthur L G Owen², Tim Künne⁶, John van der Oost⁶, Stan J J Brouns^6,7, Euan M Slorach², Chris K Fuller², Scott Gradia², Steven B Kanner², Andrew P May^2,8, Samuel H Sternberg^9,10.

Abstract

Type I CRISPR-Cas systems are the most abundant adaptive immune systems in bacteria and archaea1,2. Target interference relies on a multi-subunit, RNA-guided complex called Cascade3,4, which recruits a trans-acting helicase-nuclease, Cas3, for target degradation5-7. Type I systems have rarely been used for eukaryotic genome engineering applications owing to the relative difficulty of heterologous expression of the multicomponent Cascade complex. Here, we fuse Cascade to the dimerization-dependent, non-specific FokI nuclease domain8-11 and achieve RNA-guided gene editing in multiple human cell lines with high specificity and efficiencies of up to ~50%. FokI-Cascade can be reconstituted via an optimized two-component expression system encoding the CRISPR-associated (Cas) proteins on a single polycistronic vector and the guide RNA (gRNA) on a separate plasmid. Expression of the full Cascade-Cas3 complex in human cells resulted in targeted deletions of up to ~200 kb in length. Our work demonstrates that highly abundant, previously untapped type I CRISPR-Cas systems can be harnessed for genome engineering applications in eukaryotic cells.

Entities: Chemical

Mesh：

Year: 2019 PMID： 31740839 DOI： 10.1038/s41587-019-0310-0

Source DB: PubMed Journal: Nat Biotechnol ISSN： 1087-0156 Impact factor: 54.908

42 in total

Review 1. Genome editing with engineered zinc finger nucleases.

Authors: Fyodor D Urnov; Edward J Rebar; Michael C Holmes; H Steve Zhang; Philip D Gregory
Journal: Nat Rev Genet Date: 2010-09 Impact factor: 53.242

Review 2. TALENs: a widely applicable technology for targeted genome editing.

Authors: J Keith Joung; Jeffry D Sander
Journal: Nat Rev Mol Cell Biol Date: 2012-11-21 Impact factor: 94.444

3. In vitro reconstitution of Cascade-mediated CRISPR immunity in Streptococcus thermophilus.

Authors: Tomas Sinkunas; Giedrius Gasiunas; Sakharam P Waghmare; Mark J Dickman; Rodolphe Barrangou; Philippe Horvath; Virginijus Siksnys
Journal: EMBO J Date: 2013-01-18 Impact factor: 11.598

4. CasA mediates Cas3-catalyzed target degradation during CRISPR RNA-guided interference.

Authors: Megan L Hochstrasser; David W Taylor; Prashant Bhat; Chantal K Guegler; Samuel H Sternberg; Eva Nogales; Jennifer A Doudna
Journal: Proc Natl Acad Sci U S A Date: 2014-04-18 Impact factor: 11.205

Review 5. Diversity, classification and evolution of CRISPR-Cas systems.

Authors: Eugene V Koonin; Kira S Makarova; Feng Zhang
Journal: Curr Opin Microbiol Date: 2017-06-09 Impact factor: 7.934

6. Small CRISPR RNAs guide antiviral defense in prokaryotes.

Authors: Stan J J Brouns; Matthijs M Jore; Magnus Lundgren; Edze R Westra; Rik J H Slijkhuis; Ambrosius P L Snijders; Mark J Dickman; Kira S Makarova; Eugene V Koonin; John van der Oost
Journal: Science Date: 2008-08-15 Impact factor: 47.728

Review 7. An updated evolutionary classification of CRISPR-Cas systems.

Authors: Kira S Makarova; Yuri I Wolf; Omer S Alkhnbashi; Fabrizio Costa; Shiraz A Shah; Sita J Saunders; Rodolphe Barrangou; Stan J J Brouns; Emmanuelle Charpentier; Daniel H Haft; Philippe Horvath; Sylvain Moineau; Francisco J M Mojica; Rebecca M Terns; Michael P Terns; Malcolm F White; Alexander F Yakunin; Roger A Garrett; John van der Oost; Rolf Backofen; Eugene V Koonin
Journal: Nat Rev Microbiol Date: 2015-09-28 Impact factor: 60.633

8. Structures of the RNA-guided surveillance complex from a bacterial immune system.

Authors: Blake Wiedenheft; Gabriel C Lander; Kaihong Zhou; Matthijs M Jore; Stan J J Brouns; John van der Oost; Jennifer A Doudna; Eva Nogales
Journal: Nature Date: 2011-09-21 Impact factor: 49.962

9. Fusion of catalytically inactive Cas9 to FokI nuclease improves the specificity of genome modification.

Authors: John P Guilinger; David B Thompson; David R Liu
Journal: Nat Biotechnol Date: 2014-04-25 Impact factor: 54.908

10. Dimeric CRISPR RNA-guided FokI nucleases for highly specific genome editing.

Authors: Shengdar Q Tsai; Nicolas Wyvekens; Cyd Khayter; Jennifer A Foden; Vishal Thapar; Deepak Reyon; Mathew J Goodwin; Martin J Aryee; J Keith Joung
Journal: Nat Biotechnol Date: 2014-04-25 Impact factor: 54.908

28 in total

Review 1. Chemistry of Class 1 CRISPR-Cas effectors: Binding, editing, and regulation.

Authors: Tina Y Liu; Jennifer A Doudna
Journal: J Biol Chem Date: 2020-08-14 Impact factor: 5.157

2. Introducing Large Genomic Deletions in Human Pluripotent Stem Cells Using CRISPR-Cas3.

Authors: Zhonggang Hou; Chunyi Hu; Ailong Ke; Yan Zhang
Journal: Curr Protoc Date: 2022-02

3. A TXTL-Based Assay to Rapidly Identify PAMs for CRISPR-Cas Systems with Multi-Protein Effector Complexes.

Authors: Franziska Wimmer; Frank Englert; Chase L Beisel
Journal: Methods Mol Biol Date: 2022

4. Allosteric control of type I-A CRISPR-Cas3 complexes and establishment as effective nucleic acid detection and human genome editing tools.

Authors: Chunyi Hu; Dongchun Ni; Ki Hyun Nam; Sonali Majumdar; Justin McLean; Henning Stahlberg; Michael P Terns; Ailong Ke
Journal: Mol Cell Date: 2022-07-13 Impact factor: 19.328