Prime editing-mediated precise knockin of protein tag sequences in the rice genome

Article Biotechnology & Applied Microbiology

Programmable deletion, replacement, integration and inversion of large DNA sequences with twin prime editing

Andrew Anzalone et al.

Summary: The twin prime editing (twinPE) method described in this study allows for programmable replacement or excision of DNA sequences at endogenous human genomic sites without the need for double-strand DNA breaks (DSBs). When combined with a site-specific serine recombinase, twinPE enables targeted integration of gene-sized DNA plasmids (>5,000 bp) and targeted sequence inversions of 40 kb in human cells. TwinPE expands the capabilities of precision gene editing and may synergize with other tools for the correction or complementation of large or complex human pathogenic alleles.

NATURE BIOTECHNOLOGY (2022)

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Letter Biochemistry & Molecular Biology

Multiplex precision gene editing by a surrogate prime editor in rice

Huiyuan Li et al.

MOLECULAR PLANT (2022)

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Article Biotechnology & Applied Microbiology

An engineered prime editor with enhanced editing efficiency in plants

Yuan Zong et al.

Summary: In this study, we have improved the editing efficiency of prime editing by engineering the structure of the prime editor and combining it with specific guide RNAs. The optimized prime editor showed significantly increased editing efficiency in plant cells, and when combined with engineered guide RNAs, it resulted in the generation of herbicide-tolerant rice plants.

NATURE BIOTECHNOLOGY (2022)

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Article Biochemical Research Methods

Efficient targeted insertion of large DNA fragments without DNA donors

Jinlin Wang et al.

Summary: GRAND editing is a technique that enables efficient insertion of large DNA fragments without the need for DNA donors. By using a pair of prime editing guide RNAs and nonhomologous reverse transcription templates, it achieves high insertion efficiency in multiple cell lines and non-dividing cells.

NATURE METHODS (2022)

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Letter Biology

Improving the efficiency of prime editing with epegRNAs and high-temperature treatment in rice

Jinpeng Zou et al.

SCIENCE CHINA-LIFE SCIENCES (2022)

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Letter Biochemistry & Molecular Biology

Optimized prime editing efficiently generates glyphosate-resistant rice plants carrying homozygous TAP-IVS mutation in EPSPS

Yuanyuan Jiang et al.

MOLECULAR PLANT (2022)

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Article Biotechnology & Applied Microbiology

Development of a highly efficient prime editor 2 system in plants

Juan Li et al.

Summary: In this study, an enhanced plant Prime Editor 2 system (enpPE2) is developed to improve editing efficiency. The results demonstrate that enpPE2 is a robust and powerful tool for precise modification of plant genomes.

GENOME BIOLOGY (2022)

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Article Plant Sciences

A design optimized prime editor with expanded scope and capability in plants

Wen Xu et al.

Summary: This study demonstrated that using N-terminal reverse transcriptase-Cas9 nickase fusion and introducing multiple-nucleotide substitutions in the reverse transcriptase template can significantly enhance the efficiency of prime editing in plants and human cells. The optimized approach achieved higher editing frequencies compared to the original editor, Prime Editor 3, showing the potential to make previously non-editable target sites editable and expand the capabilities of prime editing in the future.

NATURE PLANTS (2022)

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Article Biotechnology & Applied Microbiology