Quantitative assessment of engineered Cas9 variants for target specificity enhancement by single-molecule reaction pathway analysisopen access
- Authors
- Bak, So Young; Jung, Youngri; Park, Jinho; Sung, Keewon; Jang, Hyeon-Ki; Bae, Sangsu; Kim, Seong Keun
- Issue Date
- Nov-2021
- Publisher
- OXFORD UNIV PRESS
- Citation
- NUCLEIC ACIDS RESEARCH, v.49, no.19, pp 11312 - 11322
- Pages
- 11
- Indexed
- SCIE
SCOPUS
- Journal Title
- NUCLEIC ACIDS RESEARCH
- Volume
- 49
- Number
- 19
- Start Page
- 11312
- End Page
- 11322
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/202580
- DOI
- 10.1093/nar/gkab858
- ISSN
- 0305-1048
1362-4962
- Abstract
- There have been many engineered Cas9 variants that were developed to minimize unintended cleavage of off-target DNAs, but detailed mechanism for the way they regulate the target specificity through DNA:RNA heteroduplexation remains poorly understood. We used single-molecule FRET assay to follow the dynamics of DNA:RNA heteroduplexation for various engineered Cas9 variants with respect to on-target and off-target DNAs. Just like wild-type Cas9, these engineered Cas9 variants exhibit a strong correlation between their conformational structure and nuclease activity. Compared with wild-type Cas9, the fraction of the cleavage-competent state dropped more rapidly with increasing base-pair mismatch, which gives rise to their enhanced target specificity. We proposed a reaction model to quantitatively analyze the degree of off-target discrimination during the successive process of R-loop expansion. We found that the critical specificity enhancement step is activated during DNA:RNA heteroduplexation for evoCas9 and HypaCas9, while it occurs in the post-heteroduplexation stage for Cas9-HF1, eCas9, and Sniper-Cas9. This study sheds new light on the conformational dynamics behind the target specificity of Cas9, which will help strengthen its rational designing principles in the future.
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