Proximity determines donor candidacy during DNA double-stranded break homology directed repair

Charles D. Yeh(ETH Zurich), Lilly van de Venn(ETH Zurich), Susanne Kreutzer(ETH Zurich), Xinhe Zheng(ETH Zurich), Naomi Cantos(ETH Zurich), Markus Schroeder(ETH Zurich), Robin Hofmann(ETH Zurich), Felix Ezequiel Gerbaldo(ETH Zurich), Alexandra Clemens(ETH Zurich), Beeke Wienert(University of California, Berkeley), Chris D. Richardson(University of California, Berkeley), Zacharis Kontarakis(ETH Zurich), Jacob E. Corn(ETH Zurich)
bioRxiv (Cold Spring Harbor Laboratory)
February 10, 2025
10.1101/2025.02.10.637161
Cited by 1

Abstract

Abstract DNA double-stranded breaks (DSBs) are especially toxic events that can be reversed by homology-directed repair (HDR), wherein information is copied from an intact template molecule. RAD51 mediates initial DSB/template pairing during homology search. A major challenge in understanding homology search in cells is the lack of tools to monitor this process. We developed RA D51 p roximity id entification seq uencing (RaPID-seq), a sensitive method that marks all candidate templates searched by RAD51. We find that HDR is hierarchical, such that DSB proximity determines template candidacy and subsequent recombination is unlocked by DSB/template homology. Sequences that lie outside the proximal window are not efficiently searched, even if identical in sequence. Our data reveal the invisible process of homology search and shed new light on fundamental mechanisms underlying genome editing.

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