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Nickase fidelity drives EvolvR-mediated diversification in mammalian cells

Author

Listed:
  • Juan E. Hurtado

    (Berkeley)

  • Adam J. Schieferecke

    (Berkeley
    Berkeley)

  • Shakked O. Halperin

    (Berkeley)

  • John Guan

    (Berkeley)

  • Dylan Aidlen

    (Berkeley)

  • David V. Schaffer

    (Berkeley
    Berkeley
    Berkeley
    Berkeley)

  • John E. Dueber

    (Berkeley
    Berkeley
    Lawrence Berkeley National Laboratory)

Abstract

In vivo genetic diversifiers have previously enabled efficient searches of genetic variant fitness landscapes for continuous directed evolution. However, existing genomic diversification modalities for mammalian genomic loci exclusively rely on deaminases to generate transition mutations within target loci, forfeiting access to most missense mutations. Here, we engineer CRISPR-guided error-prone DNA polymerases (EvolvR) to diversify all four nucleotides within genomic loci in mammalian cells. We demonstrate that EvolvR generates both transition and transversion mutations throughout a mutation window of at least 40 bp and implement EvolvR to evolve previously unreported drug-resistant MAP2K1 variants via substitutions not achievable with deaminases. Moreover, we discover that the nickase’s mismatch tolerance limits EvolvR’s mutation window and substitution biases in a gRNA-specific fashion. To compensate for gRNA-to-gRNA variability in mutagenesis, we maximize the number of gRNA target sequences by incorporating a PAM-flexible nickase into EvolvR. Finally, we find a strong correlation between predicted free energy changes underlying R-loop formation and EvolvR’s performance using a given gRNA. The EvolvR system diversifies all four nucleotides to enable the evolution of mammalian cells, while nuclease and gRNA-specific properties underlying nickase fidelity can be engineered to further enhance EvolvR’s mutation rates.

Suggested Citation

  • Juan E. Hurtado & Adam J. Schieferecke & Shakked O. Halperin & John Guan & Dylan Aidlen & David V. Schaffer & John E. Dueber, 2025. "Nickase fidelity drives EvolvR-mediated diversification in mammalian cells," Nature Communications, Nature, vol. 16(1), pages 1-13, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-58414-0
    DOI: 10.1038/s41467-025-58414-0
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    References listed on IDEAS

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    1. Ralf Schmidt & Carl C. Ward & Rama Dajani & Zev Armour-Garb & Mineto Ota & Vincent Allain & Rosmely Hernandez & Madeline Layeghi & Galen Xing & Laine Goudy & Dmytro Dorovskyi & Charlotte Wang & Yan Yi, 2024. "Base-editing mutagenesis maps alleles to tune human T cell functions," Nature, Nature, vol. 625(7996), pages 805-812, January.
    2. Shakked O. Halperin & Connor J. Tou & Eric B. Wong & Cyrus Modavi & David V. Schaffer & John E. Dueber, 2018. "CRISPR-guided DNA polymerases enable diversification of all nucleotides in a tunable window," Nature, Nature, vol. 560(7717), pages 248-252, August.
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