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Find and cut-and-transfer (FiCAT) mammalian genome engineering

Author

Listed:
  • Maria Pallarès-Masmitjà

    (Pompeu Fabra University)

  • Dimitrije Ivančić

    (Pompeu Fabra University
    Barcelona Institute of Science and Technology)

  • Júlia Mir-Pedrol

    (Pompeu Fabra University)

  • Jessica Jaraba-Wallace

    (Pompeu Fabra University)

  • Tommaso Tagliani

    (Pompeu Fabra University)

  • Baldomero Oliva

    (Pompeu Fabra University)

  • Amal Rahmeh

    (Pompeu Fabra University)

  • Avencia Sánchez-Mejías

    (Pompeu Fabra University)

  • Marc Güell

    (Pompeu Fabra University)

Abstract

While multiple technologies for small allele genome editing exist, robust technologies for targeted integration of large DNA fragments in mammalian genomes are still missing. Here we develop a gene delivery tool (FiCAT) combining the precision of a CRISPR-Cas9 (find module), and the payload transfer efficiency of an engineered piggyBac transposase (cut-and-transfer module). FiCAT combines the functionality of Cas9 DNA scanning and targeting DNA, with piggyBac donor DNA processing and transfer capacity. PiggyBac functional domains are engineered providing increased on-target integration while reducing off-target events. We demonstrate efficient delivery and programmable insertion of small and large payloads in cellulo (human (Hek293T, K-562) and mouse (C2C12)) and in vivo in mouse liver. Finally, we evolve more efficient versions of FiCAT by generating a targeted diversity of 394,000 variants and undergoing 4 rounds of evolution. In this work, we develop a precise and efficient targeted insertion of multi kilobase DNA fragments in mammalian genomes.

Suggested Citation

  • Maria Pallarès-Masmitjà & Dimitrije Ivančić & Júlia Mir-Pedrol & Jessica Jaraba-Wallace & Tommaso Tagliani & Baldomero Oliva & Amal Rahmeh & Avencia Sánchez-Mejías & Marc Güell, 2021. "Find and cut-and-transfer (FiCAT) mammalian genome engineering," Nature Communications, Nature, vol. 12(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-27183-x
    DOI: 10.1038/s41467-021-27183-x
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    References listed on IDEAS

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    1. Keiichiro Suzuki & Yuji Tsunekawa & Reyna Hernandez-Benitez & Jun Wu & Jie Zhu & Euiseok J. Kim & Fumiyuki Hatanaka & Mako Yamamoto & Toshikazu Araoka & Zhe Li & Masakazu Kurita & Tomoaki Hishida & Mo, 2016. "In vivo genome editing via CRISPR/Cas9 mediated homology-independent targeted integration," Nature, Nature, vol. 540(7631), pages 144-149, December.
    2. Andrew V. Anzalone & Peyton B. Randolph & Jessie R. Davis & Alexander A. Sousa & Luke W. Koblan & Jonathan M. Levy & Peter J. Chen & Christopher Wilson & Gregory A. Newby & Aditya Raguram & David R. L, 2019. "Search-and-replace genome editing without double-strand breaks or donor DNA," Nature, Nature, vol. 576(7785), pages 149-157, December.
    3. Sanne E. Klompe & Phuc L. H. Vo & Tyler S. Halpin-Healy & Samuel H. Sternberg, 2019. "Transposon-encoded CRISPR–Cas systems direct RNA-guided DNA integration," Nature, Nature, vol. 571(7764), pages 219-225, July.
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