Bridge recombinase enables versatile rewriting of bacterial genomes

  1. Jaymin R. Patel
  2. Sophia E. Swartz
  3. Agnès Oromí-Bosch
  4. Liana Yong
  5. Zachary W. LaTurner
  6. Jack E. Demaray
  7. Angela Voelker
  8. Ryuichi Ono
  9. Patrick Vu
  10. Preeti Rao
  11. Hannah Luskin
  12. Pia Andrade
  13. Michael L. Cui
  14. Givi Mchedlishvili
  15. Madeline M. Hayes
  16. Natalie Aluwihare
  17. Carlos E. Iglesias-Aguirre
  18. Emma C. MacKenzie
  19. Cynthia I. Rodriguez
  20. Suzanne Devkota
  21. Spencer Diamond
  22. Brady F. Cress
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Abstract

Bacteria drive crucial processes across ecosystems and impact human health, yet tools to rewrite microbiomes remain limited. Here, we show that bridge recombinase enables versatile and programmable genome editing across the bacterial tree of life. In Escherichia coli , we achieved 142 kb insertions at >90% efficiency, megabase-scale inversions (2.3 Mb), and pathway-scale 50 kb excisions. With a single ortholog and bridge RNA (bRNA), we edited bacterial isolates spanning five phyla and diverse members of two human gut communities. We overcame cross-reactivity between co-expressed bRNAs to establish search-and-replace Targetable Recombinase Assisted DNA Exchange (TRADE) editing and demonstrated capture and interphylum transfer of chromosomal pathways, enabling programmable horizontal gene transfer. These advances establish bridge recombinase as a foundation for reprogramming gene flow in complex microbial communities.

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  1. Version published to 10.64898/2026.04.29.721476 on bioRxiv