<p>Adenine base editors (ABEs), which enable A•T-to-G•C base editing, have emerged as a powerful tool with potential therapeutic applications. However, conventional ABEs suffer from bystander nucleotide conversions, limiting their utility for precise editing. Here we present a single-nucleotide resolution ABE (snuABE) created by fusing a nickase Cas9, nCas9-H840A, with the deaminase domain of ADAR (adenosine deaminase acting on RNA), which acts on DNA:RNA hybrids, instead of TadA, which acts on single-stranded DNA in conventional ABEs. snuABE requires a target-adenine guide RNA (tagRNA) that introduces a mismatch at the target adenine, enabling highly specific A-to-G editing by ADAR. Engineering ADAR from <i>Pediculus</i> <i>humanus</i> using the in silico protein evolution algorithm EvolvePro, along with 3′-end protection of the tagRNA, enhanced snuABE activity, yielding a median efficiency of 5.4% and a maximum efficiency of 50.0% across 32 targets in HEK293T cells. snuABE exhibits no detectable DNA off-target editing at predicted off-target or orthogonal R-loop sites, highlighting its potential as a precise and safe base-editing technology.</p>

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Engineered ADARs enable precision A-to-G base editing of DNA

  • Hyeon Woo Im,
  • Bada Jeong,
  • Yeji Lee,
  • Ye Eun Oh,
  • Chanju Jung,
  • Yong-Woo Kim,
  • Doyoon Kim,
  • Soyoon Lee,
  • Heesoo Uhm,
  • Yohan Kim,
  • Sangsu Bae

摘要

Adenine base editors (ABEs), which enable A•T-to-G•C base editing, have emerged as a powerful tool with potential therapeutic applications. However, conventional ABEs suffer from bystander nucleotide conversions, limiting their utility for precise editing. Here we present a single-nucleotide resolution ABE (snuABE) created by fusing a nickase Cas9, nCas9-H840A, with the deaminase domain of ADAR (adenosine deaminase acting on RNA), which acts on DNA:RNA hybrids, instead of TadA, which acts on single-stranded DNA in conventional ABEs. snuABE requires a target-adenine guide RNA (tagRNA) that introduces a mismatch at the target adenine, enabling highly specific A-to-G editing by ADAR. Engineering ADAR from Pediculus humanus using the in silico protein evolution algorithm EvolvePro, along with 3′-end protection of the tagRNA, enhanced snuABE activity, yielding a median efficiency of 5.4% and a maximum efficiency of 50.0% across 32 targets in HEK293T cells. snuABE exhibits no detectable DNA off-target editing at predicted off-target or orthogonal R-loop sites, highlighting its potential as a precise and safe base-editing technology.