Search

Your search keyword '"Yaoge Jiao"' showing total 6 results
Start Over Author "Yaoge Jiao" Language undetermined
6 results on '"Yaoge Jiao"'

1. Bi-PE: bi-directional priming improves CRISPR/Cas9 prime editing in mammalian cells

Author

Rui Tao, Yanhong Wang, Yaoge Jiao, Yun Hu, Li Li, Lurong Jiang, Lifang Zhou, Junyan Qu, Qiang Chen, and Shaohua Yao

Subjects
Gene Editing, Mammals, Genetics, Animals, Deoxyribonuclease I, DNA Breaks, Double-Stranded, RNA-Directed DNA Polymerase, CRISPR-Cas Systems, RNA, Guide, Kinetoplastida
Abstract

Prime editors consisting of Cas9-nickase and reverse transcriptase enable targeted precise editing of small DNA pieces, including all 12 kinds of base substitutions, insertions and deletions, while without requiring double-strand breaks or donor templates. Current optimized prime editing strategy (PE3) uses two guide RNAs to guide the performance of prime editor. One guide RNA carrying both spacer and templating sequences (pegRNA) guides prime editor to produce ssDNA break and subsequent extension, and the other one produces a nick in the complementary strand. Here, we demonstrated that positioning the nick sgRNA nearby the templating sequences of the pegRNA facilitated targeted large fragment deletion and that engineering both guide RNAs to be pegRNAs to achieve bi-direction prime editing (Bi-PE) further increase the efficiency by up to 16 times and improved the accuracy of editing products by 60 times. In addition, we showed that Bi-PE strategy also increased the efficiency of simultaneous conversion of multiple bases but not single base conversion over PE3. In conclusion, Bi-PE strategy expanded the editing scope and improved the efficiency and the accuracy of prime editing system, which might have a wide range of potential applications.

Published
2022

2. WT-PE: Prime editing with nuclease wild-type Cas9 enables versatile large-scale genome editing

Author

Rui Tao, Yanhong Wang, Yun Hu, Yaoge Jiao, Lifang Zhou, Lurong Jiang, Li Li, Xingyu He, Min Li, Yamei Yu, Qiang Chen, and Shaohua Yao

Subjects
Gene Editing, Cancer Research, Genetics, RNA-Directed DNA Polymerase, CRISPR-Cas Systems, RNA, Guide, Kinetoplastida
Abstract

Large scale genomic aberrations including duplication, deletion, translocation, and other structural changes are the cause of a subtype of hereditary genetic disorders and contribute to onset or progress of cancer. The current prime editor, PE2, consisting of Cas9-nickase and reverse transcriptase enables efficient editing of genomic deletion and insertion, however, at small scale. Here, we designed a novel prime editor by fusing reverse transcriptase (RT) to nuclease wild-type Cas9 (WT-PE) to edit large genomic fragment. WT-PE system simultaneously introduced a double strand break (DSB) and a single 3′ extended flap in the target site. Coupled with paired prime editing guide RNAs (pegRNAs) that have complementary sequences in their 3′ terminus while target different genomic regions, WT-PE produced bi-directional prime editing, which enabled efficient and versatile large-scale genome editing, including large fragment deletion up to 16.8 megabase (Mb) pairs and chromosomal translocation. Therefore, our WT-PE system has great potential to model or treat diseases related to large-fragment aberrations.

Published
2022

4. Expanding PAM recognition and enhancing base editing activity of Cas9 variants with non-PI domain mutations derived from xCas9

Author

Lifang Xie, Yun Hu, Li Li, Lurong Jiang, Yaoge Jiao, Yanhong Wang, Lifang Zhou, Rui Tao, Junyan Qu, Qiang Chen, and Shaohua Yao

Subjects
Gene Editing, Amino Acid Substitution, CRISPR-Associated Protein 9, Mutation, Cell Biology, CRISPR-Cas Systems, Molecular Biology, Biochemistry
Abstract

The recognition of protospacer adjacent motif (PAM) is a key factor for the CRISPR (i.e. clustered regularly interspaced short palindromic repeats)/CRISPR-associated 9 (Cas9) system to distinguish foreign DNAs from the host genome, and also significantly restricts the targeting scope of the system during genome-editing applications. Structurally, the PAM interacting (PI) domain, which usually is located in the C-terminus of Cas9 proteins, directly binds to PAM and plays a key role in determining the recognition specificity. However, several lines of evidence showed that other regions of Cas9 protein beyond the PI domain might also play roles in PAM interaction. Here, we constructed a mosaic SpCas9 protein (xCas9-NG) by fusing the PI domain of SpCas9 PAM variant, Cas9-NG with the non-PI fragment of xCas9 protein that contains multiple amino acid substitutions. We found that non-PI fragment of xCas9 expanded PAM recognition of the Cas9-NG PI domain. In addition, xCas9-NG showed an improved editing efficiency in the majority of targets harboring xCas9 and Cas9-NG PAMs. Importantly, this finding was also successfully extended to other Cas9 variants, including SpRY and the non-G SpCas9 series. Together, our work expands the target scope of SpCas9 editing system and demonstrates the notion that the non-PI domain fragment plays an important role in PAM restriction.

Published
2022

5. A split cytosine deaminase architecture enables robust inducible base editing

Author

Lifang Zhou, Yanhong Wang, Lurong Jiang, Fengming Qin, Qiang Chen, Wenling Tang, Junyan Qu, Yaoge Jiao, Li Li, Yun Hu, Nan Liu, Rui Tao, Shaohua Yao, Lifang Xie, and Jie Long

Subjects
Gene Editing, Computer science, Base pair, APOBEC1, Cytosine deaminase, Proteins, DNA, Computational biology, Base (topology), Biochemistry, Genome, Cytidine Deaminase, RNA splicing, Genetics, Humans, CRISPR, CRISPR-Cas Systems, APOBEC3A, Molecular Biology, Biotechnology
Abstract

Directed base substitution with base editing technology enables efficient and programmable conversion of C:G or A:T base pairs to T:A or G:C in the genome. Although this technology has shown great potentials in a variety of basic research, off-target editing is among one of the biggest challenges toward its way to clinical application. Base editing tools, especially the tools converting C to T, caused unpredictable off-target editing throughout the genome, which raise the concern that long-term application of these tools would induce genomic instability or even tumorigenesis. To overcome this challenge, we designed an inducible base editing tool that was active only in the presence of a clinically safe chemical, rapamycin. In the guidance of structural information, we designed four split-human APOBEC3A (A3A) -BE3 base editors in which these A3A deaminase enzymes were split at sites that were opposite to the protein-nucleotide interface. We showed that by inducible deaminase reconstruction with a rapamycin responsible interaction system (FRB and FKBP); three out of four split-A3A-derived base editors showed robust inducible base editing. However, in the absence of rapamycin, their editing ability was dramatically inhibited. Among these split editors, splicing at Aa85 of A3A generated the most efficient inducible editing. In addition, compared to the full-length base editor, the splitting did not obviously alter the editing window and motif preference, but slightly increased the product purity. We also expanded this strategy to another frequently used cytosine deaminase, rat APOBEC1 (rA1), and observed a similar induction response. In summary, these results demonstrated the concept that splitting deaminases is a practicable method for timely controlling of base editing tools.

Published
2021

6. HDAC inhibitors improve CRISPR-Cas9 mediated prime editing and base editing

Author

Nan Liu, Lifang Zhou, Guifeng Lin, Yun Hu, Yaoge Jiao, Yanhong Wang, Jingming Liu, Shengyong Yang, and Shaohua Yao

Subjects
Drug Discovery, Molecular Medicine
Abstract

Recent advances in CRISPR-Cas9 techniques, especially the discovery of base and prime editing, have significantly improved our ability to make precise changes in the genome. We hypothesized that modulating certain endogenous pathway cells could improve the action of those editing tools in mammalian cells. We established a reporter system in which a small fragment was integrated into the genome by prime editing (PE). With this system, we screened an in-house small-molecule library and identified a group of histone deacetylase inhibitors (HDACi) increasing prime editing. We also found that HDACi increased the efficiency of both cytosine base editing (CBE) and adenine base editing (ABE). Moreover, HDACi increased the purity of cytosine base editor products, which was accompanied by an upregulation of the acetylation of uracil DNA glycosylase (UNG) and UNG inhibitor (UGI) and an enhancement of their interaction. In summary, our work demonstrated that HDACi improves Cas9-mediated prime editing and base editing.

Published
2021

Catalog

Books, media, physical & digital resources
See catalog results