Litcius/Paper detail

Circular RNA-mediated inverse prime editing in human cells

Ronghong Liang, Shan Wang, Yanmei Cai, Zhenyu Li, Kai Li, Jingjing Wei, Chao Sun, Haocheng Zhu, Kunling Chen, Caixia Gao

2025Nature Communications13 citationsDOIOpen Access PDF

Abstract

Prime editors are restricted to performing precise edits downstream of cleavage sites, thereby limiting their editing scope. Therefore, we develop inverse prime editors (iPEs) that act upstream of the nickase cleavage site by replacing nCas9-H840A with nCas9-D10A, but the editing efficiencies are limited. To address this limitation, we develop circular RNA-mediated iPEs (ciPEs), achieving editing efficiencies ranging from 0.1% to 24.7%. Further optimization using Rep-X helicase increases editing efficiencies to a range of 2.7%–55.4%. The Rep-X-assisted ciPE system thus expands the scope of editing and improves efficiencies at genomic sites that are previously difficult to target. The Rep-X-assisted ciPE system will complement canonical PE system in enabling more extensive and efficient editing across a wider range of the human genome. Prime editors are restricted to performing precise edits downstream of cleavage sites. Here, authors develop helicase-assisted circular RNA-mediated inverse PEs (ciPEs) to increase editing efficiencies at previously challenging genomic sites, expanding the scope of precise genome editing.

Topics & Concepts

Prime (order theory)RNAInverseCircular RNAComputational biologyComputer scienceBiologyCell biologyCombinatoricsMathematicsGeneticsGeneGeometryCRISPR and Genetic EngineeringRNA regulation and diseaseVirus-based gene therapy research